Freeze-fracture studies on barley plastid membranes. VI. Location of the P700-chlorophyll a-protein 1

The photosystem I mutant of barley, viridis-zb63, which totally lacks the P700-chlorophyll a-protein 1 was characterised by rotary shadowed, freeze-fracture electron microscopy. Objective measurements were made of particle density and size distribution for all four fracture faces, and compared with values for wild-type. A highly significant reduction in the size of the PFu particles was found, which could be attributed to the loss of a population of large particles from the mutant PFu face. A corresponding loss of EFu pits was also observed. It is concluded that the photosystem I reaction centre and two or three ancillary polypeptides are located in the large PFu particles which account for two-thirds of the total, and that these particles span the membrane. Since no differences were seen on the PFs and EFs faces, there was no evidence for the localisation of any photosystem I in appressed granal membranes, supporting the concept of extreme lateral heterogeneity. A model is presented of the localisation of different functional polypeptide units to different freeze-fracture particles within the membrane. A peculiar feature of viridis-zb63 thylakoids was the presence of EFs particle arrays in vivo.     

Effects of Photoperiod on Supramolecular Architecture of Thylakoid Membranes from a Rice Mutant (Oryza sativa Nongken 58S)

Plants of a rice mutant (Hubei photoperiod-sensitive genic male-sterile rice, Oryza sativa L. Nongken 58S) and its wild type cv. Nongken 58 were cultured in natural summer conditions in Beijing. After induction of proper photoperiods small panicle at the stem tip emerged and developed to the stage of secondary rachis-branch and spikelet primordium formation. Subsequently, part of the rice plants received long day (LD), i.e. 10 h of day-light treatment followed by 5 h of white fluorescent illumination with 1～2 Wm-2) . The others were exposed to daylight for 10 h alternating with a 14 h of dark period as short day (SD) treatment. After 10 days of the photoperiodic treatments, the chloroplast ultrastructure of the first leave below the flag leaf was examined by freeze-fracture rotary and unidirectionally shadowed electron microscopy. At anthesis stage, Nongken 58S plants with LD treatment showed complete pollen sterility, while the same plants with SD treatment exhibited normal fertility. And fertility of Nongken 58 was not affected by photoperiod treatments. The results from electron microscopic observation showed no significant effects of either SD or LD treatment on the freeze-fractured uhrastructure of thylakoid membranes in Nongken 58. No significant difference in particle density and size distribution was found on stacked and unstacked thylakoid membrane regions of the Nongken 58S-SD and those of Nongken 58 rice. However, the particle density of the endoplasmic fracture face in the staked region (EFs) and protoplasmic fracture face in the staked region (PFs) faces detected from the leaf thylakoid membranes of Nongken 58S-SD rice was significantly higher than that of the corresponding faces from Nongken 58S-LD. In some cases much more particles on EFs faces of thylakoid membranes isolated from Nongken 58S-SD rice appeared as paracrystalline particle array, indicating increases in the number of PS Ⅱ reaction centres, LHC I and Cyt b6/f per unit area of thylakoid membrane. The particle density of the endoplasmic fracture face in the unstaked region (EFu) and protoplasmic fracture face in the unstaked region (PFu) faces from unstacked thylakoid membranes of Nongken 58S-LD was less than that of the corresponding faces from Nongken 58S-SD. And the particle density of PFu faces from margin and end of the membranes of the grana thylakoids of LD-treated Nongken 58S leaves was also less than that of unstacked thylakoid membranes from SDtreated rice. In severe cases, most of the particles on endoplasmic fracture face in the unstaked region (EFu) and protoplasmic fracture face in the unstaked region (PFu) faces were even missing, indicating a decrease in the numbers of photosystem Ⅰ , LHCⅠ , Cyt b6/f and ATPase per unit area of' thylakoid membrane. The above results could further provide an augmentation for explaning the photoperiod-sensitive genic male-sterility.     

Changes of Freeze-Fracture Ultrastructure and Light Harvesting Chlorophyll Protein Complex in Thylakoid Membranes During Ontogeny of Maize

Freeze-fracture electron microscopy enables us to observe and count the freeze-fracture particles which correspond to the different functional components of thylakoid membranes. The present paper reports the observation on freeze-fracture ultrastructure of thylakoid membranes and the analysis of proteins by the SDS-polyacrylamide gel electrophoresis within the membranes from differenly located leaves of maize. In the past, we found that the leaies subtending the ear of maize had a much higher chlorophyll content, a lower chlorophyll a/b ratio and more staking thylakoid membranes and provided the photosynthetic energy used to fill the maize seeds more than that of other leaves. Recently, we have further found that the particle densities of all four faces of thylakoid membranes from the ear leaf were the highest, than those, successively, from the terminal leaf, and the fifth leaf (from the base of the plant). The particle densities on all four fracture faces of thylakoid membranes isolated from the ear leaves of maize were significantly higher than those from the terminal leaves with the increases of 19% in EFs, 28% in PFs and 20% in PFu. Increases in particle densities on the PFs, EFs and PFu faces result in increased densities of LHCP II, PSⅡ and PSI reactions centres, respectively. It is significant that this supramolecular architecture of the ear leaves is consistent with our analytical results of the SDS-polyacrylamide gel electrophoresis within the membranes (a detailed report in another paper). The contents of major polypeptides of 21 kD (LHCP Ⅰ) and 25 kD (LHCP Ⅱ) in thylakoid membranes from the ear leaves were more than those from the terminal leaves. The characteristics of both supramolecular architecture and polypeptide components are in favour of absorbing, transferring, distributing and conversing light energy in the course of photosynthesis of the ear leaves in maize.     

Freeze-fracture studies on barley plastid membranes. VII. Structural changes associated with phosphorylation of the light-harvesting complex

Chloroplast thylakoid membranes were isolated from barley at room temperature under redox conditions which ensured that the light-harvesting complex was either non-phosphorylated or phosphorylated. The ultrastructural appearance of these membranes was characterised by rotary shadowed, freeze-fracture electron microscopy. Upon phosphorylation, there was a slight (5%) decrease in the extent of thylakoid stacking, as evidenced by an increase in EFu face particle density. It was concluded from detailed measurements of particle density and size distribution that phosphorylation of the light-harvesting complex results in the movement of some of the Photosystem II EFs particles and some of the PFs particles containing the light-harvesting complex from grana to stroma membranes. There was also a slight increase in PFs particle size and the appearance of a population of large particles on this face, which may be due to conformational changes in the light-harvesting complex or to the movement of some Photosystem I particles from stroma to grana membranes.     

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

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

The light-harvesting chlorpohyll-protein complex of photosystem II. Its location in the photosynthetic membrane

We have investigated the structure of the photosynthetic membrane in a mutant of barley known to lack a chlorophyll-binding protein. This protein is thought to channel excitation energy to photosystem II, and is known as the "light-harvesting chlorophyll-protein complex." Extensive stacking of thylakoids into grana occurs in both mutant and wild-type chloroplasts. Examination of membrane internal structure by freeze-fracturing indicates that only slight differences exist between the fracture faces of mutant and wild-type membranes. These differences are slight reductions in the size of particles visible on the EFs fracture face, and in the number of particles seen on the PFs fracture face. No differences can be detected between mutant and wild-type on the etched out surface of the membrane. In contrast, tetrameric particles visible on the etched inner surface of wild-type thylakoids are extremely difficult to recognize on similar surfaces of the mutant. These particles can be recognized on inner surfaces of the mutant membranes when they are organized into regular lattices, but these lattices show a much closer particle-to-particle spacing than similar lattices in wild-type membranes. Although several interpretations of these data are possible, these observations are consistent with the proposal that the light-harvesting chlorophyll-protein complex of photosystem II is bound to the tetramer (which is visible on the EFs face as a single particle) near the inner surface of the membrane. The large tetramer, which other studies have shown to span the thylakoid membrane, may represent an assembly of protein, lipid, and pigment comprising all the elements of the photosystem II reaction. A scheme is presented which illustrates one possibility for the light reaction across the photosynthetic membrane.     

Ultrastructural organization of chloroplast membranes in mutants of Pisum sativum L. with impaired activity in the photosystems

The ultrastructural organization and the photosynthesis reactions of chloroplast membranes were studied in three lethal mutants of Pisum sativum, Chl-1, Chl-19 and Chl-5, all lacking the capacity to evolve oxygen. The rates of 2,6-dichloroindophenol reduction, delayed fluorescence and electron-spin-resonance signal 1 indicate that Chl-1 and Chl-19 have an impaired activity in photosystem II (PS II), while in Chl-5 the electron transport is blocked between PS I and the reactions of CO₂ fixation. Ultrathin sectioning demonstrates the presence of giant grana in the chloroplasts of Chl-1 and Chl-19, while the chloroplast structure of the Chl-5 is very similar to that of the wild-type. The grana of the Chl-19 mutant contain large multilamellar regions of tightly packed membranes. When the chloroplast membranes were studied by freeze-fracture, the exoplasmic and protoplasmic fracture faces (EF and PF, respectively) in both stacked and unstacked membranes were found to show large differences in particle concentrations and relative population area (per m²), and also in particle size distribution, between all mutant chloroplast membranes and the wild-type. A close correlation between increasing k_mt (ratio of particle concentrations on PF/EF) and PS II activity was observed. The differences in particle concentrations on both fracture faces in different regions of the intact chloroplast membranes of the wild-type are the consequence of a rearrangement of existing membrane components by lateral particle movements since quantitative measurements demonstrate almost complete conservation of intramembrane particles in number and size during the stacking of stroma thylakoid membranes. The results indicating particle movements strongly support the concept that the chloroplast membranes have a highly dynamic structure.Abbreviations DPIP 2,6-dichloroindophenol - EF and PF exoplasmic and protoplasmic fracture faces, respectively - PS I and PS II photosystems I and II, respectively     

Ultrastructure and freeze-fracture studies of the thylakoids ofMantoniella squamata (Prasinophyceae)

Summary The ultrastructure and the supramolecular organization of the thylakoids of the small green flagellate,Mantoniella squamata, were examined in thin sections and freeze-fracture preparations. The whole chloroplast is tightly packed with thylakoids, which show a pattern of meandering, branching and/or anastomosing membranes. In freeze-fracture preparations only two fracture-faces can be distinguished: the PF- and the EF-face. The PF-face has a much higher particle density than the EF-face (PF: 4086 particles/m²; EF: 865 particles/m²). The EF-face is not as uniform as the PF-face. The areas which are packed with particles probably correspond to closely appressed thylakoid regions or adhesive patches, noticed in thin sections in some areas. The mean particle size on both faces is also different (EF: 10.5 nm; PF: 8.6 nm), but no information about the classification of the particles to special protein complexes is available at this time.Abbreviations chl chlorophyll - EF exoplasmic fracture face - ER endoplasmic reticulum - LHC light-harvesting chlorophyll-protein complex - PF protoplasmic fracture face - PS I photosystem I - PS II photosystem II     

Alteration of thylakoid membrane structure in Brassica rapa ssp. oleifera during ageing in high and low light

Abstract Alterations in the composition and structure of thylakoids were studied in Brassica rapa ssp. oleifera grown under high and low irradiance (800 μmol m^?2 s^?1 and 80 μmol m^?2 s^?1). During ageing, both high and low light induced a decrease in total protein particle density and in the relative amount of 80–90 Å cytochrome b6/f and 90–100 Å ATP-synthetase. The density of PSII complexes in stacked (EFs) and unstacked (EFu) thylakoids also decreased. In high light, a shift was noted towards smaller PSII complexes in the EFs face with decreasing attached antenna complex CP29, but the relative amount of the antenna chlorophyll a-protein complexes of photosystem II (CPa) remained stable. In contrast, the proportion of peripheral LHCH on the PFs face and the density of PFs particles increased together with an increase in grana size. In low light, a shift occurred towards larger PSII complexes on the EFs face, along with a decrease in the proportion of CPa complexes and the PFs particle density (peripheral LHCH), though a marked increase was observed in the proportion of chlorophyll a/b-protein complexes in SDS-PAGE. The amount of photosystem I in green gel remained fairly stable, although the density of PFu particles (including PSI) increased in low and slightly diminished in high light. The results indicate that the organization of thylakoid components depends strongly on the light conditions and stage of development.     

Quantitative analysis of intramembranous particles in the membranous system of rat liver cells at different stages of development and aging

The density of intramembranous protein particles was studied by freeze-fracture. Particle density on the fracture faces of the plasmalemma and the rough endoplasmic reticulum (RER), as well as the outer and inner membranes of the nucleus and the mitochondria in rat hepatocytes were quantified. Comparison among different age groups sampled days postcoitum (dpc), days postpartum (dpp), and months postpartum (mpp) shows age-related changes in particle density in each membrane system. With the exception of the RER, particle densities increased after the 16th dpc, reached a maximum at birth, and then decreased with increasing age. Simultaneously, the number nuclear pores shows a positive correlation with the particle density of the nuclear membranes. The particle density on the membranes of the RER shows a maximum on the 16th dpc, and on the 6th dpp. Thereafter, the density of the RER decreases slightly. In all membrane systems, the density of the particles on the external fracture faces is more variable than the density of the particles on the protoplasmic fracture faces.     

FREEZE FRACTURE STUDY OF THYLAKOIDS OF FUCUS SERRATUS1

Freeze-fractured thylakoids of Fucus serratus L. exhibit three types of faces with a particle density analogous to that of EFs, EFu and PF faces of green plants. However the particle size distribution is unimodal in the three types with a mean of about 8 nm. No obvious distinction between PFs and PFu faces could be detected. The absence on EFs faces of the distinct class of large particles (>13 nm) existing in green plant thylakoids implies a unique organization of pigment proteins, especially of the light-harvesting complexes.     

A freeze-fracture electron microscope study of Trichomonas vaginalis Donné and Tritrichomonas foetus (Riedmüller)

Two strains of Trichomonas vaginalis, JH162A , with low pathogenicity, and Balt 44, with high pathogenicity, as well as one highly pathogenic strain, KV-1, of Tritrichomonas foetus were studied by freeze-fracture electron microscopy. The protoplasmic faces ( PFs ) of the cell membranes of all three strains of both species had similar numbers of intramembranous particles (IMPs); however, the particles in the external faces (EFs) of these membranes were least abundant in Trichomonas vaginalis strain Balt 44 and most numerous in those of strain JH162A of this species. In Tritrichomonas foetus strain KV-1 the number of IMPs in the EF was close to but somewhat lower than that in the mild strain of the human urogenital trichomonad . In both species, the anterior, but not the recurrent, flagella had rosette-like formations, consisting of approximately 9 to 12 IMPs on both the PFs and EFs. The numbers and distribution of the rosettes appeared to vary among different flagella and in different areas of individual flagella of a single organism belonging to either species. The freeze-fracture electron micrographs provided a more complete understanding of the fine structure of undulating membranes of Trichomonadinae , as represented by Trichomonas vaginalis, and of Tritrichomonadinae (the Tritrichomonas augusta -type), as exemplified by Tritrichomonas foetus, than was gained from previous transmission and scanning electron microscope studies. Typically three longitudinal rows of IMPs on the PF of the recurrent flagellum of Trichomonas vaginalis were noted in the area of attachment of this flagellum to the undulating membrane. The functional aspects of the various structures and differences between certain organelles revealed in the two trichomonad species by the freeze-fracture method are discussed.     

A COMPARISON OF CHLOROPLAST MEMBRANE SURFACES VISUALIZED BY FREEZE-ETCH AND NEGATIVE STAINING TECHNIQUES; AND ULTRASTRUCTURAL CHARACTERIZATION OF MEMBRANE FRACTIONS OBTAINED FROM DIGITONIN-TREATED SPINACH CHLOROPLASTS

Spinach chloroplast lamellae were washed free of negatively staining surface particles (carboxydismutase and coupling factor protein) and the resulting smooth-surfaced lamellae still showed the usual large (175 A) and small (110 A) particles seen by freeze-etching. Therefore, the freeze-fracture plane probably occurs along an internal surface of the chloroplast membrane. Fractions obtained by differential centrifugation of digitonin-treated chloroplast membranes were studied by negative staining, thin sectioning, and freeze-etching techniques for electron microscopy. The material sedimenting between 1,000 g and 10,000 g, enriched in photosystem II activity, was shown to consist of membrane fragments. These freeze-etched membrane fragments were found to have large particles on most of the exposed fracture faces. The large particles had the same size and distribution pattern as the 175 A particles seen in intact chloroplast membranes. The material sedimenting between 50,000 g and 144,000 g, which had only photosystem I activity, was found to consist of particles in various degrees of aggregation. Freeze-etching of this fraction revealed only small particles corresponding to the 110 A particles seen in intact chloroplasts. A model is presented suggesting that chloroplast lamellar membranes have a binary structure, which digitonin splits into two components. The two membrane fragments have different structures, revealed by freeze-etching, and different photochemical and biochemical functions.     

A Freeze-Fracture Electron Microscope Study of Trichomonas vaginalis Donné and Tritrichomonas foetus (Riedmüller)1

Two strains of Trichomonas vaginalis, JH162A, with low pathogenicity, and Balt 44, with high pathogenicity, as well as one highly pathogenic strain, KV-1, of Tritrichomonas foetus were studied by freeze-fracture electron microscopy. The protoplasmic faces (PFs) of the cell membranes of all three strains of both species had similar numbers of intramembranous particles (IMPs); however, the particles in the external faces (EFs) of these membranes were least abundant in Trichomonas vaginalis strain Balt 44 and most numerous in those of strain JH162A of this species. In Tritrichomonas foetus strain KV-1 the number of IMPs in the EF was close to but somewhat lower than that in the mild strain of the human urogenital trichomonad. In both species, the anterior, but not the recurrent, flagella had rosette-like formations, consisting of ～9 to 12 IMPs on both the PFs and EFs. The numbers and distribution of the rosettes appeared to vary among different flagella and in different areas of individual flagella of a single organism belonging to either species. The freeze-fracture electron micrographs provided a more complete understanding of the fine structure of undulating membranes of Trichomonadinae, as represented by Trichomonas vaginalis, and of Tritrichomonadinae (the Tritrichomonas augusta-type), as exemplified by Tritrichomonas foetus, than was gained from previous transmission and scanning electron microscope studies. Typically three longitudinal rows of IMPs on the PF of the recurrent flagellum of Trichomonas vaginalis were noted in the area of attachment of this flagellum to the undulating membrane. The functional aspects of the various structures and differences between certain organelles revealed in the two trichomonad species by the freeze-fracture method are discussed.     

Microsomal T system: a stereological analysis of purified microsomes derived from normal and dystrophic skeletal muscle

Heterogeneous populations of microsomes obtained from normal and dystrophic chicken pectoralis muscle were separated into two subfractions by an iterative loading technique. The buoyant density of the sarcoplasmic reticulum (SR) microsomes was increased after loading them with calcium oxalate. Several incubations in the transport medium were necessary to load all of the SR. The fraction that did not form a pellet contained microsomes which displayed freeze-fracture faces that had a low density of particles. A stereological analysis was used on membrane fracture faces of intact muscle to generate reference particle density distributions, which were compared with the distributions measured on the microsomal fracture faces. The concave microsomal fracture faces of purified microsomes which did not load calcium oxalate had particle distributions nearly identical to the distributions of intact P-face T tubules. The morphological data suggest that this subfraction is microsomal T system. Biochemical measurements show negligible amounts of specific Na+, K+-ATPase activity, suggesting that there was little contamination from the surface membrane in this subfraction. Furthermore, an active Ca2+-ATPase is demonstrated in both normal and dystrophic T-tubular membranes.     

The eyespot of the flagellateTetraselmis cordiformis stein (Chlorophyceae): Structural spezialization of the outer chloroplast membrane and its possible significance in phototaxis of green algae

Summary The eyespot region of the flagellateTetraselmis cordiformis Stein (Chlorophyceae) was investigated with the freeze-fracture technique. The only fracture faces observed in this region were the two complementary fracture faces (PF and EF) of the outer chloroplast envelope membrane. Intramembranous particle numbers on both fracture faces of this membrane were significantly higher in the eyespot region as compared to regions outside the eye-spot. Higher numbers of particles on the PF face in the eyespot region were mainly caused by an increase in particle numbers of the size class 6–8 mm, while on the EF face particle size distribution was not significantly different between eyespot and other regions. Functional implications are discussed and evidence is presented that the outer chloroplast envelope membrane may be the site of photoreceptor location in green algal phototaxis.     

Ultrastructure of cell wall and photosynthetic apparatus of the phycobilisome-less Synechocystis sp. strain BO 8402 and phycobilisome-containing derivative strain BO 9201

The ultrastructures of two closely related strains of a novel diazotrophic cyanobacterium, Synechocystis sp. BO 8402 and BO 9201, were examined using ultrathin sections and freeze-fracture electron microscopy. Cells of both strains were surrounded by an unusual thick peptidoglycan layer. Substructures in the layer indicated the presence of microplasmodesmata aligned perpendicular to the free cell surface and in the septum of dividing cells. Synechocystis sp. strain BO 8402 contained lobed, electronopaque, highly fluorescent inclusion bodies consisting of phycocyanin-linker complexes. The thylakoids lacked phycobilisomes and accommodated, in addition to randomly distributed exoplasmic freeze-fracture particles, patches of two-dimensionally ordered arrays of dimeric photosystem II particles in the exoplasmic fracture face. Determination of photosystem I and photosystem II suggested an increase of photosystem II in strain BO 8402. Strain BO 9201 performed phycobilisome-supported photosynthesis and showed rows of dimeric photosystem II particles in the exoplasmic fracture face. Corresponding particle-free grooves in the protoplasmic fracture face were lined by a class of large particles tentatively assigned as trimers of photosystem I. The different lateral organization of protein complexes in the thylakoid membranes and the fine structure of the cell wall are discussed with respect to absorption cross-section of photosynthesis and nitrogen fixation.Abbreviations EF Exoplasmic freeze-fracture face - P 700 Reaction centre chlorophyll of photosystem I - PF Protoplasmic freeze-fracture face - PS I Photosystem I - PS II Photosystem II     

Comparison, by freeze-fracture electron microscopy, of chromatophores, spheroplast-derived membrane vesicles, and whole cells of Rhodopseudomonas sphaeroides.

By using freeze-fracture electron microscopy, chromatophores and spheroplast-derived membrane vesicles from photosynthetically grown Rhodopseudomonas sphaeroides were compared with cytoplasmic membrane and intracellular vesicles of whole cells. In whole cells, the extracellular fracture faces of both cytoplasmic membrane and vesicles contained particles of 11-nm diameter at a density of about 5 particles per 10(4) nm2. The protoplasmic fracture faces contained particles of 11 to 12-nm diameter at a density of 14.6 particles per 10(4) nm2 on the cytoplasmic membrane and a density of 31.3 particles per 10(4) nm2 on the vesicle membranes. The spheroplast-derived membrane fraction consisted of large vesicles of irregular shape and varied size, often enclosing other vesicles. Sixty-six percent of the spheroplast-derived vesicles were oriented in the opposite way from the intracellular vesicle membranes of whole cells. Eighty percent of the total vesicle surface area that was exposed to the external medium (unenclosed vesicles) showed this opposite orientation. The chromatophore fractions contained spherical vesicles of uniform size approximately equal to the size of the vesicles in whole cells. The majority (79%) of the chromatophores purified on sucrose gradients were oriented in the same way as vesicles in whole cells, whereas after agarose filtration almost all (97%) were oriented in this way. Thus, on the basis of morphological criteria, most spheroplast-derived vesicles were oriented oppositely from most chromatophores.     

Hierarchical Response of Light Harvesting Chlorophyll-Proteins in a Light-Sensitive Chlorophyll b-Deficient Mutant of Maize

The light-sensitive chlorophyll b (Chl b)-deficient oil yellow-yellow green (OY-YG) mutant of maize (Zea mays) grown under conditions of high light exhibits differential reductions in the accumulation of the three major Chl b-containing antenna complexes and characteristic changes in thylakoid architecture. When observed by freeze-fracture electron microscopy, the most notable changes in the OY-YG thylakoid structure are: (a) a major reduction in the number of 8 nanometer particles of the protoplasmic fracture face of stacked membrane regions (PFs) paralleled by a 60% reduction in the chlorophyll-proteins (CP) associated with the peripheral light harvesting complex (LHCII) for photosystem II (PSII) and which give rise to the LHCII oligomer/monomer (CPII^*/CPII) bands on mildly dissociated green gels; (b) a sizable decrease in the proportion of 11 to 13 nanometer particles of the protoplasmic fracture face of unstacked membrane regions (PFu) that parallels the loss of light harvesting complex I (LHCI) antennae from photosystem I (PSI) centers and a 40% reduction of the band containing CP1 and LHCI (CPI^*) on mildly dissociating green gels; (c) an unchanged or slightly increased average size of particles of the exoplasmic fracture face of stacked (or appressed) membrane regions (EFs) along with a relative increase in CP29, the postulated bound LHC of PSII, and of CP47 and CP43, PSII core antenna complexes. This latter result sets the OY-YG mutant apart from all other Chl b-deficient mutants studied to date, all of which possess EFs particles that are substantially reduced in size. Based on these findings, we postulate that the bound LHCII associated with EFs particles consists mostly of CP29 chlorophyll proteins and very little, if any, CPII^*/CPII chlorophyll proteins. Indeed, the CPII^*/CPII chlorophyll proteins may be exclusively associated with the `peripheral' LHCII units that give rise to 8 nanometer PF particles. The differential effect of the Chl b deficiency on the accumulation of the three main antenna complexes (CPII^*/CPII>CPI^*>CP29) suggests, furthermore, that there is a hierarchy among Chl b-binding proteins, and that this hierarchy might be an integral part of long-term photoregulation mediating Chl b partitioning in the chloroplast.     

Ultrastructure of Acaryochloris marina, an oxyphotobacterium containing mainly chlorophyll d

We present a detailed investigation of the ultrastructure of the chlorophyll a/d-containing unicellular oxyphotobacterium Acaryochloris marina, combining light and transmission electron microscopy and showing freeze fractures of this organism for the first time. The cells were 1.8-2.1 microm x 1.5-1.7 microm in size. The cell envelope consisted of a peptidoglycan layer of approximately 10 nm thickness combined with an outer membrane. Cell division was intermediate between the constrictive and the septum type. The nucleoplasm, which contained several carboxysomes, was surrounded by 7-11 concentrically arranged thylakoids, which were predominantly stacked, with the exception of distinct areas where phycobiliproteins were located. The thylakoids were perforated by channel-like structures connecting the central and peripheral portions of the cytoplasm and not yet observed in other organisms. In freeze fractures, the protoplasmic fracture faces of thylakoid membranes were densely covered with particles of inhomogenous size. The particle size histogram peaked at 10-11, 13 and 18 nm. The 18-nm particles are assumed to represent photosystem I trimers. The particles on exoplasmic fracture faces, proposed to represent photosystem II complexes, were significantly larger than the corresponding particles of cyanobacteria and clustered to form large aggregates. This kind of arrangement is unique among photosynthetic organisms.