Freeze-Fracture Study of Blastocystis hominis1

The ultrastructure of Blastocystis hominis was investigated by the freeze-fracture method. Freeze-fracture replicas of the membranes of B. hominis and its organelles were studied with special regard to the density and distribution of the intramembranous particles (IMF's). On all membrane replicas, the concentration of IMF's on the protoplasmic face (P face) invariably was greater than on the exoplasmic face (E face). On the P face, IMP's were heterogeneously distributed in dense aggregates, alternating with particle-free, smooth surface areas. Occasionally, small depressions and protrusions were observed in these areas. On the membrane of the central vacuole, invaginations into the vacuole were frequently observed within the smooth surface regions. Since most of the granules in the central vacuoles had no IMF's, it seems likely that the intervacuolar granules were formed from these invaginations of the vacuole membrane. The width of the intermembrane space between the inner and outer membranes of the nuclear envelope was uneven, with regions of relative narrowness interspersed with regions of expansion. Nuclear pores were localized within the narrow portions of this space. A nucleus, apparently in the process of dividing, was observed enclosed within an intact outer membrane. Division of the outer membrane would then result in the formation of two discrete nuclei.     

Phagocytosis of bacteria by polymorphonuclear leukocytes: a freeze-fracture, scanning electron microscope, and thin-section investigation of membrane structure

The changes in membrane structure of rabbit polymorphonuclear (PMN) leukocytes during bacterial phagocytosis was investigated with scanning electron microscope (SEM), thin-section, and freeze-fracture techniques. SEM observations of bacterial attachment sites showed the involvement of limited areas of PMN membrane surface (0.01-0.25μm(2)). Frequently, these areas of attachment were located on membrane extensions. The membrane extensions were present before, during, and after the engulfment of bacteria, but were diminished in size after bacterial engulfment. In general, the results obtained with SEM and thin-section techniques aided in the interpretation of the three-dimensional freeze-fracture replicas. Freeze-fracture results revealed the PMN leukocytes had two fracture faces as determined by the relative density of intramembranous particles (IMP). Membranous extensions of the plasma membrane, lysosomes, and phagocytic vacuoles contained IMP's with a distribution and density similar to those of the plasma membrane. During phagocytosis, IMPs within the plasma membrane did not undergo a massive aggregation. In fact, structural changes within the membranes were infrequent and localized to regions such as the attachment sites of bacteria, the fusion sites on the plasma membrane, and small scale changes in the phagocytic vacuole membrane during membrane fusion. During the formation of the phagocytic vacuole, the IMPs of the plasma membrane appeared to move in with the lipid bilayer while maintaining a distribution and density of IMPs similar to those of the plasma membranes. Occasionally, IMPs were aligned to linear arrays within phagocytic vacuole membranes. This alignment might be due to an interaction with linearly arranged motile structures on the side of the phagocytic vacuole membranes. IMP-free regions were observed after fusion of lysosomes with the phagocytic vacuoles or plasma membrane. These IMP-free areas probably represent sites where membrane fusion occurred between lysosomal membrane and phagocytic vacuole membrane or plasma membrane. Highly symmetrical patterns of IMPs were not observed during lysosomal membrane fusion.     

Membrane interactions between adjacent mucols secretion granules

In primate goblet cells, the membranes of adjacent mucous granules from contact areas which appear as extensive pentalaminar fusion sites in thin sections. In freeze-fracture replicas, the same membrane areas are smooth, except for a few 6-8-nm particles which adhere to the E face. These protein-poor membrane interaction sites are relatively long-lived, and it is proposed that further stimulus may be required to trigger membrane fission.     

The structure and function of the smooth septate junction in a transporting epithelium: The malpighian tubules of the new zealand glow-worm Arachnocampa luminosa

Junctional complexes between the epithelial cells in the four distinct regions of the glow-worm Malpighian tubule were investigated by electron microscopy using thin sectioning, freeze-fracturing, osmotic disruption and tracer techniques. The lateral plasma membranes of all four cell types are joined by smooth septate junctions but the extent of the complex across the cell depth varies in the four different regions. The width of the septa, the interseptal spacing and the separation between the outer leaflets of the adjacent plasma membranes are different for each cell type. Gap junctions were identified only in the junctional complex between Type IV cells and were intercalated amongst large lateral sinuses. In oblique sections of lanthanum infiltrated tissue, the electron-lucent septa at the basal side of the junction are outlined by the tracer as it penetrates. In the Junctional complexes of all four regions the septa appear as short, distinct, linear bars. In tangential sections of gap junctions between Type IV cells, the junctions appear as a hexagonal array of intermembrane particles with a centre to centre spacing of 18 nm. Horseradish peroxidase did not penetrate the junctional complexes very far but readily passed through the basal lamina into the spaces between extracellular invaginations of the basement membrane of the cells. Junctional complexes in all four areas of the tubule have similar freeze-fracture faces. In freeze-fracture replicas of fixed tissue continuous ridges of fused particles are seen on the P face and complementary furrows are found on the E face. Junctional response to osmotically adjusted Ringer solutions was similar in all four cell types. Distortion or ‘blistering’ of the intercellular space between the septa of the junction occurred when the tissue was bathed in or injected with a hypertonic Ringer solution. The structure of these junctions, visualized by the different techniques, and the role of the septate junction in a transporting epithelium, are discussed.     

Phagosome fusion vesicles of Paramecium. II. Freeze-fracture evidence for membrane replacement

Phagosome fusion vesicles (PFVs), a new population of relatively large granules in Paramecium caudatum which fuse with the first stage of digestive vacuoles (DV-I) shortly after these vacuoles are released from the cytopharynx (their site of formation), have been studied by using the freeze-fracture technique. Identification of PFVs is possible in the resulting replicas at all sites where they are commonly found in thin sections, at the cytopharynx, bound but not fused with nascent digestive vacuoles and fused with released vacuoles in the cell's posterior end. These PFVs have membranes which do not resemble the membranes of the forming digestive vacuole membrane or the discoidal vesicle membranes from which vacuole membrane is derived. Their smooth E-fracture face with only 50 to 100 intramembrane particles (IMPs) per micrometers 2 and particulate P-face (approximately 2500 IMPs/micrometers) do resemble the second vacuole stage (DV-II) which is characterized by a smaller diameter and acid pH. Evidence is presented for PFV fusion with the DV-I and for membrane replacement, at least in part, as the DV-I becomes a DV-II. Membrane replacement entails first adding PFVs to the DV-I and then removing the original discoidal vesicle-derived membrane as tubules as the vacuole condenses. Implications of the possible role of PFVs in forming intravacuolar symbiotic relationships are also discussed.     

Morphological features of the surface of the sea urchin (Arbacia punctulata) egg: Oolemma-cortical granule association

Scanning microscopy and transmission electron microscopy of sectioned specimens and freeze-fracture replicas revealed the presence of slightly elevated regions, approximately one-fourth to one-half the diameter of microvilli, which were situated along the surface of unfertilized Arbacia eggs. These modifications of the surface of the egg were observed in areas occupied by cortical granules and were greatly reduced in number following the cortical granule reaction. Few such modifications were present in immature and urethane-treated ova, in which cortical granules were located in regions of the egg other than the cortex. Freeze-fracture replicas of unfertilized eggs revealed a significantly higher density of intramembranous particles within the plasmalemma when compared to replicas of the membrane surrounding cortical granules. Areas characteristic of the cortical granule membrane, i.e., sparsely laden with particles, were not observed within the plasmalemma of the fertilized egg. Hence, following its fusion with the egg plasma membrane there is a dramatic reorganization in particle distribution of the membrane derived from cortical granules.     

Plasmalemma Invaginations in Cultured Callus of Stevia rebaudiana: Ultrastructure and Ultracytochemical Localization of Acid Phosphatase

The plasmalemma of cells within meristematic regions was observed to possess invaginations in cultured callus of Stevia rebaudiana under differentiation. The ultrastructure and acid phosphatase (AcPase) ultracytochemistry Of these invaginations were studied. The plasmalemma invaginations occurred in the cells at various stages of vacuolation. In cells with dense protoplasm, plasmalemma appeared undulated but occasionally spherical and variable in size with conspicuous invaginations that projected into the peripheral cytoplasm. In the partially vacuolated cells, plasmalemma invagination became voluminously enlarged with increased contents and structurally complexed. In vacuolated cells, the enlarged invaginations protruded into the central vacuole but were delimitted from the tonoplast by an intermembrane zone continuous with the peripheral cytoplasm. Complex accumulations of membranes consisting of vesicular and coiled membranous Structures might develop within the plasmalemma invaginations. AcPase localization demonstrated high enzymic activity in the plasmalemma and its associated invagination. It seemed likely that these invaginations were functionally analogous to the vacuoles and therefore constituted part of the lytic compartment in these cells.     

甜菊愈伤组织中的质膜内陷:超微结构和酸性磷酸酶细胞化学定位

对在分化条件下的甜菊 (Stevia rebaudiana)愈伤组织分生区域细胞的质膜内陷进行了超微结构和酸性磷酸酶细胞化学研究。结果表明 ,在不同液泡化状态的细胞中均有质膜内陷存在。在原生质浓密的细胞中 ,质膜呈起伏的波纹状 ,某些部位发生明显内陷 ,大小不等 ,多呈圆球状。在部分液泡化细胞中 ,质膜内陷体积增大 ,内含物增多且结构复杂。在液泡化细胞中 ,质膜内陷嵌入中央液泡 ,但彼此间以一膜间隙隔开。质膜内陷中的内含物以小泡和卷绕的膜结构形式存在。酸性磷酸酶活性定位结果显示 ,质膜及其内陷含高的酶活性。推测质膜内陷在功能上与液泡相似 ,构成了这些细胞水解空间的一部分。     

Endocytosis by human platelets: metabolic and freeze-fracture studies

The mechanism by which platelets endocytose or release particulate or soluble substances is poorly understood. Engulfed materials enter the open canalicular system (OCS) by a process akin to phagocytosis, but fusion of platelet granules with the OCS is rarely observed. Secretion of granule contents, a concomitant of the "release reaction" which occurs during platelet aggregation, does not take place by extrusion at the surface membrane as is true for other secretory cells. Some substances may be secreted without obvious granule loss. To examine whether structural properties of the platelet membrane could account for this unusual behavior, thin section and freeze-fracture analyses were performed on platelets which had undergone endocytosis under a variety of experimental conditions. After freeze-cleavage, most of the intramembranous particles (IMP) remain associated with the outer leaflet of the platelet plasma membrane. The sites where the OCS reaches the surface membrane are marked by pits on the cytoplasmic leaflet (P face) and by complementary protrusions on the outer leaflet (E face) of the membrane. Endocytosis of small particles and solutes takes place via these structures. This process is not energy dependent but arrested at 4 degrees C. Distension of the OCS does not appear to affect the size or number of the pits. On the other hand, large particles are taken up by membrane invagination without redistribution of IMP's and independent of the pits. This process is sensitive to metabolic inhibition. Thus, the studies have demonstrated the existence of two different pathways for platelet endocytosis which are postulated to be also involved in secretion. The selective release of substances contained in different granules may be related to the "inside-out" structure of the plasma and OCS membranes.     

Fine Structure of Microgametocytes and Macrogametes of Eimeria nieschulzi

SYNOPSIS. An electron microscope study of microgametocytes and macrogametes of Eimeria nieschulzi Dieben, 1924 revealed that they lie within vacuoles bounded by a host unit membrane. The vacuole surrounding the microgametocyte contains granular material. The vacuole around the macrogamete is narrower and contains vesicles and membranes. Micropores were seen on the surface of the plasma membrane of microgametocytes and macrogametes. Microtubules were seen in macrogametes. Young microgametocytes and macrogametes have a similar cytoplasmic matrix, mitochondria and nuclei. Glycogen granules apparently develop around vacuoles in both microgametocytes and macrogametes. Glycogen granules were also seen along the margins of parallel bundles of fibers in microgametocytes. As nuclei of the microgametocyte divide, they move to the periphery of the parasite. Three basal bodies, each with 9 fibers in triplet form, develop in association with each nucleus. Microgametes have 2 free flagella and a central short, attached flagellum. Basal granules lie along the outer fibers of the central flagellum. Each microgamete has an elongate mitochondrion in close contact with the nucleus. In macrogametes wall-forming bodies develop in lacunae in the cytoplasm. Smaller dark bodies with areas of low density were also seen. Wall-forming bodies and dark bodies move to the periphery of mature macrogametes.     

DEVELOPMENT OF PERIPHERAL VACUOLES IN PLANT CELLS

The vacuolar apparatus of various plant cells consists of two distinct features: the large central vacuole and peripheral vacuoles which are derived from invaginations of the plasma membrane. Peripheral vacuoles are conspicuous structures in both living and fixed hair or filament cells of Tradescantia virginiana. They occur as spherical structures along the inner boundary of the peripheral cytoplasm and can be recognized as projections into the central vacuole. These structures are variable in size and number within a cell and can represent a significant proportion of the volume of the vacuole. Peripheral vacuoles most frequently are observed in motion with the streaming cytoplasm although their velocity is usually somewhat slower that that of the cytoplasmic organelles. Ultrastructural studies show two closely approximated membranes, one for each vacuole, in areas where a peripheral vacuole projects into the central vacuole. These are separated by an intermembrane zone continuous with the peripheral cytoplasm. The movement of organelles over the perimeter of the peripheral vacuole is presumed to occur along this intermembrane zone. The internal area of the peripheral vacuoles may appear empty although some contain a vesicular content of unknown origin and function.     

William Trager: An Appreciation

SYNOPSIS. Additional information on host interactions with trypanosomatid membranes was obtained from studies of a monomorphic strain of Trypanosoma brucei harvested at peak parasitemia from intact and lethally irradiated rats. Pellets of trypanosomes were fixed briefly in glutaraldehyde and processed for thin section electron microscopy or freeze-cleave replicas. Observations of sectioned material facilitated orientation and comparison of details seen in replicas. Fracture faces of cell body and flagellar membranes as well as 3-dimensional views of the nuclear membrane were studied. Cell body membranes of 80% of the organisms from intact rats contained random arrays of intramembranous particles (IMP). Aggregated clusters of particles appeared on the fracture faces of 20% of the trypanosomes. Some of these membranes had nonrandomly distributed particles aligned in distinct rows on the outer fracture face of both cell body and flagellum. Many inner face fractures of the cell body membranes had a particle arrangement similar to the longitudinal alignment of cytoskeletal microtubules. No aggregated particle distribution was seen in membranes of trypanosomes harvested from lethally irradiated rats. Replicas of trypanosome pellets also had plasmanemes as a series of attached, empty, coated membrane vesicles. These structures were found in close association with, as well as widely separated from the parasites. The shedding of these vesicles and the variation of particles in cell body membranes are discussed in light of antibody-induced architectural and antigenic changes in surface properties of trypanosomatids. The convex face of the inner membrane of the nucleus also is covered with randomly arrayed particles. More IMP were observed on the inner than on the outer nuclear membranes. Images of nuclear pores were also seen. The importance of these structures in drug and developmental studies of trypanosomes is discussed. On fracture faces of the flagellar membrane there were miniature maculae adherentes, unique to the inner fracture face and occurring only at regions of membrane apposition between cell body and flagellum. Each cluster of particles exposed by the freeze-cleave method corresponds to an electron-dense plaque seen in thin section images. However, because of a unique fracture pattern, these plaques were not revealed on the apposing body membranes, as illustrated in thin sectioned organisms.     

Electron-microscopic study of the nuclear membrane of the PKEV cells during mitosis. 1. The breakdown of the nuclear membrane (prophase, prometaphase, metaphase)]

An ultrastructural study on dividing PKEV cells provided a possibility to distinguish between certain stages of their desintegration. The changes preceding fragmentation of the nuclear envelope commence with desorganization of its structural components: vanishing of granular peripherial chromatin layer; appearance of the pores without central granules; formation of deep invaginations of the nuclear membranes. The desintegration of the nuclear envelope starts from the disapearance of many pores and the appearance of perforations almost of the same size. Simultaneously, the number of polysomes is reduced on the outer membrane of the nuclear envelope and in the cytoplasm. Specific features of the nuclear envelope being lost it becomes undistinguishable from the reticulum elements. On serial sections, no contacts were observed between chromosomes and membranous elements.     

Freeze-fracture study of the trophozoite and the cyst of Entamoeba histolytica

The fine structure of the trophozoite and cyst of Entamoeba histolytica from the stool of a patient was compared using the freeze-fracture method. The intramembranous particles (IMP's) were heterogeneously distributed on the plasma membrane of the trophozoite and their density was 1139 +/- 105/micron 2 on the P face. Particle-rich depressions and linear particle arrays, reported by other investigators on cultured trophozoites, were also observed on the P face while on the E face such special particle arrangement was not recognized. Particle-free, small protrusions were frequently observed on the P face of the trophozoite membrane. The existence of these protrusions is a new finding. In the cyst, the IMP's were also distributed heterogeneously on both the P and E faces of the plasma membrane. The density of the IMP's, however, was much lower than in the trophozoite: 6 +/- 2/micron 2 on the P face and averaging less than 1/micron 2 on the E face. In freeze-fracture images, the plasma membrane of the cyst showed a variety of configurations from smooth to uneven or ridged surfaces. These morphological alterations of the plasma membrane may be attributed to the aging of the cyst. The thick wall of the cyst had a filamentous tri- or tetra-lamellar structure. The cytoplasm of the cyst was similar in structure to that of the trophozoite and the diameter of the nuclear pores was equal in both trophozoites and cysts.     

Fine Structure of Hepatozoon mocassini (Apicomplexa,Eucoccidiorida) Gamonts and Modifications of the Infected Erythrocyte Plasmalemma1

Transmission electron microscopy and scanning electron microscopy were used to investigate the fine structure of Hepatozoon mocassini gamonts and modifications of the infected erythrocyte plasmalemma. Intraerythrocytic gamonts were contained within a parasitophorous vacuole. An electron-lucid space observed between the gamont pellicle and the membrane of the vacuole corresponded to the unstained space described in light microscopy studies. Gamonts possessed a conoid, polar ring, subpellicular microtubules, four pairs of rhoptries, micronemes, ovoid granules, mitochondria with tubular cristae, and a pellicle composed of three individual unit membranes. The conoid had an anterior diameter of 320 nm, a posterior diameter of 360 nm, and a length of 150 nm. In contrast to a report on Hepatozoon aegypti, no micropore or “canopy-like structure” was observed. The plasmalemma of infected erythrocytes exhibited two types of modifications: gross membrane deformations and knobs with an electron-dense central mass. These knobs are structurally distinct from previously described membrane excrescences.     

The Supramolecular Organization of Red Algal Vacuole Membrane Visualized by Freeze-fracture

The supramolecular organization of the vacuole membrane (orof the membranes of mucilage sacs) in 27 species of red algaeis studied in replicas of rapidly frozen and fractured cells.Intramembranous particle complexes composed of four particles('tetrads' with average diameters between 8·5 and 14·5have been observed in the protoplasmic fracture (PF) face butmost clearly and more frequently in the exoplasmic fracture(EF) face of the vacuole membrane of all red algae investigated.The tetrads lie individually within the vacuole membrane orform clusters in several species and are randomly distributed.In the species Ceramium diaphanum var. strictum and Laurenciaobtusa the intramembranous particle complexes ('tetrads') havebeen observed both in the EF and PF faces of the vacuole membrane;the 'membrane tetrads' at least as regards these two speciesseem to span both the outer and inner leaflets of the vacuolemembrane ('transmembrane particles'). The occurrence of particletetrads in the plasma membrane is probably due to exocytosiseither of the Golgi vesicles or of the mucilage sacs. Tetradfrequency in the EF face of the vacuole membranes of the investigatedred algae varies between 2 and 87 µm^-2, while that ofsingle particles varies between 102 and 695 µm^-2. ThePF face of the vacuole membrane is characterized by a higherparticle density than the EF face. The particle densities ofthe PF and EF faces of the plasma membrane for a given speciesare higher than those of the corresponding fracture faces ofthe vacuole membrane. Some members of Bangiophycidae bear smallerprotein particles (diameter between 8·5 and 10·5nm) in comparison with those of Florideophycidae (diameter between10·5 and 14·5 nm). It is suggested, based uponthe particle tetrads lying in depressions of the vacuole membraneand the origin of vacuoles (mucilage sacs) from ER, that theparticle tetrads originate from the ER or the Golgi complex.Since vacuoles (mucilage sacs) in red algae, along with theGolgi complex, are involved in the synthesis and export of cellsurface polysaccharides, it could be assumed that the 'membrane-tetrads'within the vacuole membrane represent a membrane-bound multienzymecomplex, participating in the synthesis of amorphous extracellularmatrix polysaccharides.Copyright 1993, 1999 Academic Press Red algae, freeze-fracture, vacuole membrane, mucilage sacs, membrane tetrads, supramolecular organization     

Freeze-Fracture Study of the Endosymbiont of Blastocrithidia culicis1

The two unit membranes which envelope the endosymbiont of the trypanosomatid protozoon, Blastocrithidia culicis, were studied using the freeze-fracture technique. The distribution of the intramembranous particles on both fracture faces of the inner and outer membrane of the endosymbiont was analyzed in the replicas. The protoplasmic face of the inner membrane (PFi) had a higher density of membrane particles than that observed on the extracellular face (EFi), a pattern typical of plasma membranes. The extracellular face of the outer membrane (EFo) presented a density of membrane particles much higher than that observed on the P face of the outer membrane (PFo) a distribution significantly different from that found in the inner membrane of the endosymbiont and in the plasma membrane of the protozoon, but similar to that observed in Gram-negative bacteria. The data obtained support the idea that the endosymbiont of trypanosomatids represents a Gram-negative bacterium-like microorganism enveloped by two unit membranes and lacking a peptidoglycan layer and which lives in direct contact with the cytoplasm of the protozoon.     

甜菊愈伤组织细胞中的液泡膜内突和液泡内囊泡

对生长在分化培养基上的甜菊愈伤组织分生区细胞的液泡膜内突和液泡内囊泡,进行了超微结构和酸性磷酸酶细胞化学研究。在不同液泡化时期的细胞中,都存在不同大小和形态的液泡膜内突,它们有的缺乏明显的内含物;有的含有许多小泡或复杂膜系;有的含有一个较大的具许多小泡或复杂膜系的膜束缚囊泡。在液泡内还存在一些游离的液泡内囊泡,它们通常具有两层紧贴的界膜或为多层同心膜,推测它们来自液泡膜内突。ＡｃＰａｓｅ定位结果显     

Membrane particle changes attending the acrosome reaction in guinea pig spermatozoa

To examine the freeze-fracture appearance of membrane alterations accompanying the preparation of sperm membranes for fusions-the first preparatory stage occurring before physiological release of the acrosomal content, the second afterward-we induced the acrosome reaction in capacitated guinea pig spermatozoa by adding calcium to the mixture. The most common features observed before fusion of the acrosomal and plasma membranes were the deletion of fibrillar intramembranous particles from the E-fracture faces of both membranes, and the clearance of globular particles from the P face of the plasma membrane-events taking place near the terminus of the equatorial segment. Large particles, >12nm, remained not far from the cleared E-face patches. The P face of the outer acrosomal membrane is virtually clear from the outset. In addition, when fusion was completed, occasional double lines of large particles transiently embossed the P face of the plasma membrane (postacrosomal) side of the fusion zone. Behind the line of fusion, another series of particle-cleared foci emerged. We interpreted these postfusion membrane clearances as a second adaptation for sperm-egg interaction. Induction of the acrosome reaction in media containing phosphatidylcholine liposomes resulted in their apparent attachment, incorporation, or exchange in both the originally and secondarily cleared regions. Our observations support the concepts that membranes become receptive to union at particle- deficient interfaces, and that the physiologically created barren areas in freeze-fracture replicas may herald incipient membrane fusion.     

Alignment of cholesterol in the membrane bilayer

Freeze-fracture replicas of filipin-treated samples of guinea pig colon mucosa reveal areas in the membrane of the goblet cell granules labeled by filipin-cholesterol complexes (FCC) intermingled with regions patterned by "lines." The FCC and "lines" are arranged in an approximately rhombic pattern. Other membranes of the same cell or of other cells display either FCC only, aligned and occasionally ordered in "rhombs," "lines" only, with a similar pattern, or randomly distributed FCC. Optical diffraction was used to analyze and compare replicas of membranes with ordered FCC and "lines", as well as randomly distributed FCC. The results demonstrate that all these structures are reciprocally related through a common distribution pattern in the membrane. This observation supports the assumption that cholesterol has a preferential ordered distribution within the membrane bilayer.