Evidence for the role of surface-exposed segments of the light-harvesting complex in cation-mediated control of chloroplast structure and function.

Chloroplast membranes contain a light-harvesting pigment-protein complex (LHC) which binds chlorophylls a and b. A mild trypsin digestion of intact thylakoid membranes has been utilized to specifically alter the apparent molecular weights of polypeptides of this complex. The modified membrane preparations were analyzed for altered functional and structural properties. Cation-induced changes in room temperature fluorescence intensity and low temperature chlorophyll fluorescence emission spectra, and cation regulation of the quantum yield of photosystem I and II partial reactions at limiting light were lost following the trypsin-induced alteration of the LHC. Electron microscopy revealed that cations can neither maintain nor promote grana stacking in membranes which have been subjected to mild trypsin treatment. Freeze-fracture analysis of these membranes showed no significant differences in particle density or average particle size of membrane subunits on the EF fracture face; structural features of the modified lamellae were comparable to membranes which had been unstacked in a “low salt” buffer. Digitonin digestion of trypsin-treated membranes in the presence of cations followed by differential centrifugation resulted in a subchloroplast fractionation pattern similar to that observed when control chloroplasts were detergent treated in cation-free medium. We conclude that: (a) the initial action of trypsin at the thylakoid membrane surface of pea chloroplasts was the specific alteration of the LHC polypeptides, (b) the segment of the LHC polypeptides which was altered by trypsin is necessary for cation-mediated grana stacking and cation regulation of membrane subunit distribution, and (c) cation regulation of excitation energy distribution between photosystem I and II involves the participation of polypeptide segments of the LHC which are exposed at the membrane surface.     

The stacking of chloroplast thylakoids: Effects of cation screening and binding,studied by the digitonin method

The differential action of digitonin on stacked and unstacked chloroplast thylakoids was used to investigate the molecular interactions between thylakoid membranes. The yield of the heavy fraction which is obtained from chloroplasts after digitonin incubation and differential centrifugation was taken as a measure of the degree or tightness of membrane appression. The effects of various mono-, di-, and trivalent cations on the yield of the heavy fraction were studied, and the results interpreted in terms either of electrostatic screening or ion binding to the thylakoid membrane surface: Although there was some degree of cation specificity in the degree of thylakoid appression indicative of cation binding, the nonspecific screening effect was much more important in determining the overall balance of forces. It is postulated that stacking occurs in regions of low net surface charge density, with a possible segregation of excess negative charges into nonstacked regions.     

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.     

3-D modelling of chloroplast structure under (Mg) magnesium ion treatment. Relationship between thylakoid membrane arrangement and stacking

We performed for the first time three-dimensional (3D) modelling of the entire chloroplast structure. Stacks of optical slices obtained by confocal laser scanning microscope (CLSM) provided a basis for construction of 3D images of individual chloroplasts. We selected pea (Pisum sativum) and bean (Phaseolus vulgaris) chloroplasts since we found that they differ in thylakoid organization. Pea chloroplasts contain large distinctly separated appressed domains while less distinguished appressed regions are present in bean chloroplasts. Different magnesium ion treatments were used to study thylakoid membrane stacking and arrangement. In pea chloroplasts, as demonstrated by 3D modelling, the increase of magnesium ion concentration changed the degree of membrane appression from wrinkled continuous surface to many distinguished stacked areas and significant increase of the inter-grana area. On the other hand 3D models of bean chloroplasts exhibited similar but less pronounced tendencies towards formation of appressed regions. Additionally, we studied arrangements of thylakoid membranes and chlorophyll-protein complexes by various spectroscopic methods, Fourier-transform infrared spectroscopy (FTIR) among others. Based on microscopic and spectroscopic data we suggested that the range of chloroplast structure alterations under magnesium ions treatment is a consequence of the arrangement of supercomplexes. Moreover, we showed that stacking processes always affect the structural changes of chloroplast as a whole.     

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.     

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.     

Ultrastructural changes in chloroplasts resulting from fluctuations in NaCl concentration: freeze-fracture of thylakoid membranes in Dunaliella salina.

The structure of chloroplasts isolated from Dunaliella salina has been studied with respect to changing concentrations of sodium chloride in the culture medium. Freeze-fracture replicas and thin sections of intact chloroplasts do not exhibit any noticeable changes in structure at concentrations ranging between 3.5 and 25% NaCl. Chloroplasts isolated from algal cells that have been acclimatized to the higher salt concentration show a change in the thylakoid membranes. The thylakoid membranes appear compressed over a major portion of the membrane surface, with only the end of the thylakoid membranes unappressed. The number of particles per unit area on the B face is also altered by the salt concentration. The chloroplasts acclimatized to 25% NaCl have about 3 times the number of particles per unit area on a B face of end-membranes as on a comparable face of thylakoid membranes acclimatized to low (3.5% NaCl) salt concentration. These morphological changes can be reversed if the chloroplasts acclimatized to high or low salt concentrations are returned to a medium of different salt concentration prior to freeze-fracturing.     

Fine structure of the chloroplast membranes ofEuglena gracilis as revealed by freeze-cleaving and deep-etching techniques

Summary The chloroplasts ofEuglena gracilis have been examined by freeze-cleaving and deep-etching techniques.The two chloroplast envelope membranes exhibit distinct fracture faces which do not resemble any of the thylakoid fracture faces.Freeze-cleaved thylakoid membranes reveal four split inner faces. Two of these faces correspond to stacked membrane regions, and two to unstacked regions. Analysis of particle sizes on the exposed faces has revealed certain differences from other chloroplast systems, which are discussed. Thylakoid membranes inEuglena are shown to reveal a constant number of particles per unit area (based on the total particle number for both complementary faces) whether they are stacked or unstacked.Deep-etchedEuglena thylakoid membranes show two additional faces, which correspond to true inner and outer thylakoid surfaces. Both of these surfaces carry very uniform populations of particles. Those on the external surface (the A surface) are round and possess a diameter of approximately 9.5 nm. Those on the inner surface (the D surface) appear rectangular (as paired subunits) and measure approximately 10 nm in width and 18 nm in length. Distribution counts of particles show that the number of particles per unit area revealed by freeze-cleaving within the thylakoid membrane approximates closely the number of particles exposed on the external thylakoid surface (the A surface) by deep-etching. The possible significance of this correlation is discussed. The distribution of rectangular particles on the inner surface of the thylakoid sac (D surface) seems to be the same in both stacked and unstacked membrane regions. We have found no correlation between the D surface particles and any clearly defined population of particles on internal, freeze-cleaved membrane faces. These and other observations suggest that stacked and unstacked membranes are similar, if not identical in internal structure.     

Surface potential and reaction of the membrane-bound electron transfer components. II. Integrity of the chloroplast membrane and reaction of P-700

Electrostatic characteristics of the membrane in the vicinity of P-700 were estimated by analyzing the salt and detergent effects on its reaction rate with ionic reagents using the Gouy-Chapman diffuse double layer theory in various preparations of chloroplasts. Upon disruption of thylakoid membranes by sonic treatment or by treatment with digitonin, the reaction rate markedly increased, while the estimated surface charge density became smaller. It was concluded that the membrane surface which determines the reaction rate between P-700 and the ionic reagents changed as the disruption of thylakoid structure. The outer thylakoid surface had more negative charges than the inner one. Changes in the electrical potential profile across the thylakoid membrane during the illumination were also discussed from these results.     

Surface potential and reaction of the membrane-bound electron transfer components. II. Integrity of the chloroplast membrane and reaction of P-700

Electrostatic characteristics of the membrane surface in the vicinity of P-700 were estimated by analyzing the salt and detergent effects on its reaction rate with ionic reagents using the Gouy-Chapman diffuse double layer theory in various preparations of chloroplasts.

Upon disruption of thylakoid membranes by sonic treatment or by treatment with digitonin, the reaction rate markedly increased, while the estimated surface charge density became smaller.

It was concluded that the membrane surface which determines the reaction rate between P-700 and the ionic reagents changed as the disruption of thylakoid structure. The outer thylakoid surface had more negative charges than the inner one.

Changes in the electrical potential profile across the thylakoid membrane during the illumination were also discussed from these results.     

Investigations of the role of the main light-harvesting chlorophyll- protein complex in thylakoid membranes. Reconstitution of depleted membranes from intermittent-light-grown plants with the isolated complex

The functions of the light-harvesting complex of photosystem II (LHC- II) have been studied using thylakoids from intermittent-light-grown (IML) plants, which are deficient in this complex. These chloroplasts have no grana stacks and only limited lamellar appression in situ. In vitro the thylakoids showed limited but significant Mg2+-induced membrane appression and a clear segregation of membrane particles into such regions. This observation, together with the immunological detection of small quantities of LHC-II apoproteins, suggests that the molecular mechanism of appression may be similar to the more extensive thylakoid stacking seen in normal chloroplasts and involve LHC-II polypeptides directly. To study LHC-II function directly, a sonication- freeze-thaw procedure was developed for controlled insertion of purified LHC-II into IML membranes. Incorporation was demonstrated by density gradient centrifugation, antibody agglutination tests, and freeze-fracture electron microscopy. The reconstituted membranes, unlike the parent IML membranes, exhibited both extensive membrane appression and increased room temperature fluorescence in the presence of cations, and a decreased photosystem I activity at low light intensity. These membranes thus mimic normal chloroplasts in this regard, suggesting that the incorporated LHC-II interacts with photosystem II centers in IML membranes and exerts a direct role in the regulation of excitation energy distribution between the two photosystems.     

青海高原不同海拔珠芽蓼叶绿体超微结构的比较

 用电子显微镜技术观察研究了生长于青海高原3个海拔地带(2500m、3200m、3980m)的珠芽蓼(polygonum viviparum L．)叶绿体的超微结构,发现随着海拔的升高,叶绿体结构呈现显著的变化趋势。2500m和3200m处叶绿体形状规则,分布在细胞边缘。3980m处叶绿体膨大变形,且分布在整个细胞当中。海拔升高,类囊体膜减少,膜垛叠程度减小。不同海拔珠芽蓼叶绿体的类囊体膜结构差异较大,特点显著。随海拔升高,珠芽蓼叶绿体破坏程度增加。主要表现为类囊体膜肿胀、类囊体膜溶解和叶绿体破裂。许多破裂的叶绿体中残留有发达的基粒和大而多的淀粉粒。珠芽蓼叶绿体的这些结构特征,既是环境胁迫的结果,又是植物适应性的表现。     

Entropy-assisted stacking of thylakoid membranes

Chloroplasts in plants and some green algae contain a continuous thylakoid membrane system that is structurally differentiated into stacked granal membranes interconnected by unstacked thylakoids, the stromal lamellae. Experiments were conducted to test the hypothesis that the thermodynamic tendency to increase entropy in chloroplasts contributes to thylakoid stacking to form grana. We show that the addition of bovine serum albumin or dextran, two very different water-soluble macromolecules, to a suspension of envelope-free chloroplasts with initially unstacked thylakoids induced thylakoid stacking. This novel restacking of thylakoids occurred spontaneously, accompanied by lateral segregation of PSII from PSI, thereby mimicking the natural situation. We suggest that such granal formation, induced by the macromolecules, is partly explained as a means of generating more volume for the diffusion of macromolecules in a crowded stromal environment, i.e., greater entropy overall. This mechanism may be relevant in vivo where the stroma has a very high concentration of enzymes of carbon metabolism, and where high metabolic fluxes are required.     

Entropy-assisted stacking of thylakoid membranes

Chloroplasts in plants and some green algae contain a continuous thylakoid membrane system that is structurally differentiated into stacked granal membranes interconnected by unstacked thylakoids, the stromal lamellae. Experiments were conducted to test the hypothesis that the thermodynamic tendency to increase entropy in chloroplasts contributes to thylakoid stacking to form grana. We show that the addition of bovine serum albumin or dextran, two very different water-soluble macromolecules, to a suspension of envelope-free chloroplasts with initially unstacked thylakoids induced thylakoid stacking. This novel restacking of thylakoids occurred spontaneously, accompanied by lateral segregation of PSII from PSI, thereby mimicking the natural situation. We suggest that such granal formation, induced by the macromolecules, is partly explained as a means of generating more volume for the diffusion of macromolecules in a crowded stromal environment, i.e., greater entropy overall. This mechanism may be relevant in vivo where the stroma has a very high concentration of enzymes of carbon metabolism, and where high metabolic fluxes are required.     

Isoelectric points of membrane surfaces of three spinach chloroplast classes determined by cross-partition

The isoelectric points of the membranes surrounding three classes of spinach chloroplasts have been determined by partition at different pH values in aqueous two-phase systems where the electrical potential differences at the interface are opposite (cross-partition). Class I chloroplasts, intact chloroplasts, have an isoelectric point at pH 3.8–4.1 and class II chloroplasts, broken chloroplasts or intact thylakoid membranes, have an isoelectric point at pH 4.7–4.9. The third class of particles, class III ‘chloroplasts’, that contain one or more chloroplasts, mitochondria, peroxisomes and some cytoplasm all surrounded by a membrane, probably the plasma membrane, have an isoelectric point at pH 3.4–4.0. The partition technique used presumably yields the isoelectric point of the surface of the membranes exposed to the phase system by the three classes of chloroplasts, i.e., the outer envelope membrane, the thylakoid membrane and the plasma membrane, respectively. The isoelectric points obtained with this technique are suggested to reflect protein to charged-lipid differences in the composition of the membranes.     

Chloroplast biogenesis. Regulation of lipid transport to the thylakoid in chloroplasts isolated from expanding and fully expanded leaves of pea

To study the regulation of lipid transport from the chloroplast envelope to the thylakoid, intact chloroplasts, isolated from fully expanded or still-expanding pea (Pisum sativum) leaves, were incubated with radiolabeled lipid precursors and thylakoid membranes subsequently were isolated. Incubation with UDP[(3)H]Gal labeled monogalactosyldiacylglycerol in both envelope membranes and digalactosyldiacylglycerol in the outer chloroplast envelope. Galactolipid synthesis increased with incubation temperature. Transport to the thylakoid was slow below 12 degrees C, and exhibited a temperature dependency closely resembling that for the previously reported appearance and disappearance of vesicles in the stroma (D.J. Morré, G. Selldén, C. Sundqvist, A.S. Sandelius [1991] Plant Physiol 97: 1558-1564). In mature chloroplasts, monogalactosyldiacylglycerol transport to the thylakoid was up to three times higher than digalactosyldiacylglycerol transport, whereas the difference was markedly lower in developing chloroplasts. Incubation of chloroplasts with [(14)C]acyl-coenzyme A labeled phosphatidylcholine (PC) and free fatty acids in the inner envelope membrane and phosphatidylglycerol at the chloroplast surface. PC and phosphatidylglycerol were preferentially transported to the thylakoid. Analysis of lipid composition revealed that the thylakoid contained approximately 20% of the chloroplast PC. Our results demonstrate that lipids synthesized at the chloroplast surface as well as in the inner envelope membrane are transported to the thylakoid and that lipid sorting is involved in the process. Furthermore, the results also indicate that more than one pathway exists for galactolipid transfer from the chloroplast envelope to the thylakoid.     

Chloroplast membrane structure. Intramembranous particles of different sizes make contact in stacked membrane regions.

The supramolecular architecture of stacked thylakoid membrane regions of class II spinach chloroplasts has been investigated by means of freeze-fracture electron microscopy. Such membranes contain two basic types of intramembranous particles: laarge particles, which are found on the fracture face of the lumenal membrane leaflet (Bs face), and smaller ones which are found on the fracture face of the external leaflet (Cs face). By analyzing thylakoid membranes containing geometrical arrangements of intramembranous particles it is shown (a) that within the plane of each membrane approximately two small particles are associated with each large particle, and (b) that normal thylakoid stacking involves the connection of large particles of one membrane to small particles of the other and vice versa. If the two types of particles are related to Photosystems I and II, as suggested by circumstantial evidence, then our observations provide support for the idea that maximum Photosystem I-photosystem II interaction is obtained by intermembrane subunit interaction in grana stacks. To this end, our results suggest that stacking should enhance the quantum yield at very low light intensities.     

Ontogenetic Change of the PSI- and PSII-Distribution in the Thylakoid System of Euglena gracilis

The thylakoid membranes of isolated Euglena chloroplasts wereseparated into two fractions by aqueous two-phase-partitioning(mixture of dextran 500 and poly(ethylene glycol) 4000) followingpress disruption. These two fractions differ in many respectsduring most of the cell cycle of this alga in comparison withthe thylakoid characteristics of higher plants or green algae.The amount of thylakoid membranes with separation characteristicscomparable with inside-out-vesicles of higher plant chloroplastschanges depending on the cell cycle stage of Euglena gracilis.Photosystems II and I are not restricted to one fraction. Boththylakoid membrane fractions evolve oxygen photosynthetically.When chloroplast differentiation in Euglena gracilis is complete(i.e. at the end of the light-time) the composition and thephotosynthetic efficiency of the two thylakoid fractions aregenerally equal. Photosystem I-related LHCI is present in bothfractions. Photosystem II-related CP29, however, was only detectedin unfractionated thylakoid membranes. The implications forthylakoid organization in Euglena chloroplasts are discussed. Key words: Euglena gracilis, photosystem I, photosystem II, stacking, thylakoids     

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

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

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

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