A thin-section and freeze-fracture study of microfilament-membrane attachments in choroid plexus and intestinal microvilli

Choroid plexus and intestinal microvilli in thin sections have microfilaments in the cytoplasm adjacent to the membranes, and in replicas have broken strands of filaments in both cytoplasm and on E faces of plasm membranes. The microfilaments contain actin as indicated by their binding of heavy meromyosin (HMM). In sections of choroid plexus, the microfilaments are 7-8 nm in diameter and form a loose meshwork which lies parallel to the membrane and which is connected to the membranes both by short, connecting filaments (8 times 30 nm) and dense globules (approximately 15-20 nm). The filamentous strands seen in replicas are approximately 8 nm in diameter. Because they are similar in diameter and are connected to the membrane, these filamentous strands seen in replicas apparently represent the connecting structures, portions of the microfilaments, or both. The filamentous strands attached to the membrane are usually associated with the E face and appear to be pulled through the P half-membrane. In replicas of intestinal brush border microvilli, the connecting strands attaching core microfilaments to the membrane are readily visualized. In contrast, regions of attachment of core microfilaments to dense material at the tips of microvilli are associated with few particles on P faces and with few filamentous strands on the E faces of the membranes. Freeze-fracture replicas suggest a morphologically similar type of connecting strand attachment for microfilament-membrane binding in both choroid plexus and intestinal microvilli, despite the lack of a prominent core bundle of microfilaments in choroid plexus microvilli.     

Connections between the cristae and the surface of rat heart muscle mitochondria

Contrary to the generally accepted rule that there are only two fracture faces associated with a membrane, the analysis of double replicas at rat heart muscle mitochondria revealed three pairs of complementary replicas with one face in each pair exposing the outer surface membrane. The replicas must then expose the surfaces of the outer surface membrane and in two of the pairs the fracture had passed between the two surface membranes in two alternative ways, either clearly between the two membranes or the fracture deviated into and through the inner surface membrane at regularly spaced intervals. This deviation reveals that at these sites the connection between the two surface membranes is particularly firm. The analysis led to the conclusion that these sites correspond to those where the stalk-like connections extending from the cristae are connected to the inner surface membrane. This way proteinaceous pathways connect the cristae to the surface of the mitochondria.     

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.     

Freeze-fracture study of Blastocystis hominis

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 (IMP's). On all membrane replicas, the concentration of IMP'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 IMP'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.     

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.     

Rhombic particle arrays in gill epithelium of a mollusc, Aplysia californica.

Gill epithelia from adult and juvenile Aplysia were examined by conventional thin section and freeze-fracture methods. Freeze-fracture replicas of adult gill epithelium revealed septate and gap junctions, which served as membrane markers for the epithelial cells. In these same cell membranes, non-junctional rhombic arrays of intramembranous particles were observed on prominent ridges on the membrane P fracture face of some epithelial cells. In thin sections of adult epithelium, nerve terminals were observed abutting the lateral plasma membranes near the basal lamina of some epithelial cells. Correlative areas of plasma membrane in freeze-fracture replicas showed a close association between rhombic particle arrays and abutting nerve terminals. In thin sections of juvenile Aplysia, nerve terminals abutting the epithelial cells were not recognizable, and rhombic arrays were not observed in freeze-fracture replicas. This suggested that a developmental association existed between the appearance of rhombic arrays in adult epithelia and their innervation. It is not known with certainty if, in invertebrates, rhombic arrays are an essential structural entity of all innervated cell membranes; however, in the cells thus far studied, there appears to be an associative condition. In the case of the gill epithelium of Aplysia, rhombic arrays are located in the same vicinity as the abutting nerve terminals. Similar arrays of intramembranous particles have been observed in myoneural postjunctional complexes of other invertebrates and have been interpreted to be the morphological expression of neurotransmitter receptors. An analogous explanation is put forth, namely that rhombic arrays may represent the structural correlates of neurotransmitter receptors and/or ionic channels in innervated membranes of invertebrates.     

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.     

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.     

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.     

AN INTERPRETATION OF LIVER CELL MEMBRANE AND JUNCTION STRUCTURE BASED ON OBSERVATION OF FREEZE-FRACTURE REPLICAS OF BOTH SIDES OF THE FRACTURE

A modification of the freeze-fracturing technique to permit observation of replicas of both sides of the fracture is described. It has been used to study mouse liver cell membrane structure. Membranes break to give two faces with three-dimensional complementarity, although there is some small-scale mismatching which is discussed. Since the two distinctive sets of membrane faces are complementary sets, they cannot be the two outside surfaces. In particular, structures (such as particles) seen on these faces are within the membrane. It is not possible from this work to say precisely where the fracture plane goes with respect to a plasma membrane, only that it must be close to the interface between membrane and cytoplasm, or at that interface. Models, consistent with the appearance of the matching replicas, are derived for three regions of the plasma membrane: (a) The nonjunctional plasma membrane, which contains many scattered particles. Except for these particles, the otherwise flat fracture face is not at variance with a bimolecular leaflet structure. (b) Gap junctions. Each of the two membranes comprising a gap junction contains a close-packed array of particles. (c) Tight junctions. Here membranes have ridges within them.     

Intercellular junctions in myriapods

Tissue from the intestinal tract of myriapods, including millipedes, centipedes and pauropods were examined in tracer-impregnated sections and freeze-fracture replicas. The foregut and hindgut of all three classes exhibit pleated septate junctions; these display undulating intercellular ribbons in thin sections. In replicas they show discrete intramembranous particle (IMP) arrays aligned in rows in parallel; with one another. The tissues of the hindgut also possess scalariform junctions, characterized by cross-striated intercellular clefts in sections and IMP-enriched membranes in replicas. Gap junctions occur in all groups, but they are atypical in replicas in that their component IMPs do not always fracture onto the E face, as is characteristic of other arthropods; some IMPs cleave to the P face and others to the E face. The midgut of these organisms exhibits smooth septate junctions with conventional straight septal ribbons and occasional interseptal columns. However the intramembranous appearance in replicas is variable, particularly in centipedes, in that the rows of IMPs in chemically-unfixed propanecryofixed tissues, are prominent and adhere preferentially to the E face, with complementary P face grooves, while in fixed tissues the IMPs are much less distinct and fracture to either P face or E face. They tend not to protrude far beyond the mid-plane of the membrane bilayer and lie in rows which commonly take on the form of a network. Individual rows of the network sometimes curve to run beside a second row, over a short distance, before bending away into another part of the network. The aligned particle rows, which are much more prominent in millipedes, where they frequently lie in close parallel appositions, do not fuse into ridges as often occurs in insect tissues. The myriapod junctions, therefore, are of the same general kind as are found in the gut tract of other arthropod groups, but differ with respect to the subtleties of their intramembranous organization and disposition.     

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 Blastocrithidia culicis as seen in thin sections and freeze-fracture replicas

The fine structure of epimastigotes of Blastocrithidia culicis was studied by transmission electron microscopy of thin sections and freeze-fracture replicas. This parasite presents a well developed endoplasmic reticulum and Golgi complex systems. Differences in the density and organization of the intramembranous particles were observed between the membranes which enclose the cell body and the flagellum. Ridge-like elevations, visualized in freeze-fracture replicas, were observed in sites where the mitochondrial branches touched the plasma membrane. A special array of membrane particles was observed on both faces of the flagellar and the cell body membranes at the region where the flagellum adheres to the cell body. It appeared as strands made of two rows of membrane particles. Filipin-treated cells were used for the localization of membrane sterols in freeze-fracture replicas. The number of filipin-sterol complexes varied from cell to cell. In some cells, rows of filipin-sterol complexes were seen. No complexes were observed in the region of the attachment of the flagellum to the cell body.     

FREEZE-FRACTURED CHLOROPLAST MEMBRANES OF GONYAULAX POLYEDRA (PYRROPHYTA)1

The chloroplast membranes of Gonyaulax polyedra Stein were studied in replicas of rapidly frozen and fractured cells. The thylakoid EF_s face lacked the large 15–16 nm particles characteristic of plants with the light-harvesting chlorophyll a/b protein, presumably because the principal light-harvesting protein of Gonyaulax is the small water-soluble peridinin-chlorophyll-protein and the chlorophyll a/b protein is absent. As in other plants, the EF_s thylakoid fracture face carried more particles (4 ×) than EF_uface. The PF faces of the thylakoid showed twice as many particles as did the EF_s faces. No circadian differences in the number or size of thylakoid membrane particles could be detected. Three membranes comprise the chloroplast envelope in Gonyaulax. They could be clearly differentiated in freeze-fractured cells. The middle envelope membrane carried many fewer particles on both the EF and PF faces than did the other two envelope membranes. The PF faces of both the outer and inner envelope membranes showed more particles than the EF faces, as do many other membranes which have been examined.     

Virus-Induced Cytoplasmic Membrane Structures Associated with Semliki Forest Virus Infection Studied by the Freeze-Etching Method

Intracellular membrane structures associated with the Semliki Forest virus replication process were studied from freeze-etch replicas. Cleaved membrane structures inside the CPV I type vacuoles lacked the typical membrane particles present on most other fractured membranes. CPV II type vacuoles present in thin sections were obscured in the freeze-etch replicas by the cytoplasmic ground substance.     

Membrane events involved in fusion of uterine epithelial cells in pseudopregnant rabbits

Summary During pseudopregnancy in the rabbit some uterine epithelial cells undergo conversion into symplasmata. This event serves as a model for studies of membrane apposition, fusion and fission of the lateral membranes with the use of different ultrastructural techniques. Apposition of lateral membranes occurs by means of proliferation of the tight-junctional belt and macular tight junctions. Membrane fusion is characterized in freeze-fracture replicas by continuously running fracture planes between neighboring membrane leaflets of epithelial cells, in general without reorganization of the particles. It is suggested that the reorganization of particles as well as the blebs or vesicles of smooth membranes, which are occasionally observed, may be artefacts. Membrane fission occurs simultaneously with fusion resulting in irregularly shaped membrane holes on freeze-fracture replicas. These events are rarely seen in thin sections. Staining with tannic acid reveals that only the layers of the plasma membrane are accessible to this agent. The fusion-fission process starts in the lower region of the lateral membranes, whereas the luminal portion with the broad tight-junctional belt remains intact.Dedicated to Professor Dr. med. Dr. phil. Karl-Heinrich Knese, Stuttgart-Hohenheim, in honour of his 70th birthday     

Differentiation of food vacuolar membranes during endocytosis in Tetrahymena

The origin and differentiation of Tetrahymena pyriformis food vacuolar membranes has been studied by freeze-fracture electron microscopy. By measuring the temperature needed to induce the onset of lipid phase separation (as inferred by the appearance of particle-free regions in replicas) and calculating the changes in average intramembrane particle distribution, a distinct modification of the vacuolar membrane could be observed from the time of its formation from disk-shaped vesicles to its maturation before egestion of its indigestible contents. Whereas the nascent vacuolar membrane first showed signs of phase separation at 9 degrees C, this temperature rose to 14 degrees C in the completed vacuole and then, after lysosomal fusion, eventually declined to 12 degrees C. The average membrane particle density on the PF face increased from 761 +/- 219 to 1,625 +/- 350 per micron 2 during membrane differentiation. Like other membranes of the cell, the vacuolar membrane underwent adaptive changes in its physical properties in cells maintained for several hours at low temperature. This exposure to low temperature caused an equal effect in vacuoles formed before, during, or after the temperature shift-down. Normal changes in the properties of the vacuolar membrane may have some bearing on its programmed sequence of fusion reactions.     

Cholesterol localization in the membranes of granular cells in the bladder epithelium of the frog during stimulated water transport

The polyene antibiotic filipin has been used to characterize the cholesterol distribution in the membranes of resting and ADH-stimulated frog urinary bladder in freeze-fracture replicas. In general, the intracellular membranes takes up filipin only insignificantly. An exception is the cholesterol rich granule membrane. Both density and polarity of filipin-induced deformations were evaluated, and the asymmetry in membrane cholesterol was analysed. Upon ADH-stimulation of water flow both density and polarity of filipin-induced deformations altered differently in apical and basolateral regions of the plasma membrane. This difference is presumably due to the stretching of the basolateral membrane as a result of swelling, on the one hand, and to incorporation of aggregate containing membranes into the apical membrane, on the other one. The results obtained may suggest that the appearance of ADH-induced intramembranous particle aggregates in the apical membrane be accompanied with a relative cholesterol decrease in this apical membrane.     

A new type of substratum adhesion structure in NRK cells revealed by correlated interference reflection and electron microscopy

The substratum adherent membrane of NRK cells in vitro has been studied using correlated interference reflection and surface replica electron microscopy. Structures visualized by interference reflection microscopy were identified in the subsequently prepared platinum-carbon replicas of the adherent membranes. Substratum adherent membranes were prepared using a hypotonic shock/cell shearing technique (lysis-squirting). Typically 20% of the original ventral membrane surface area and 50% of the original focal adhesion number were retained. Microfilament bundle termini, clathrin-coated sheets and pits, cytotic vesicles having a ridged surface and groups of membrane associated particles were well preserved in the replicas. Two types of isolated adhesion structures were found after lysis-squirting. In addition to typical elongate focal adhesions containing actin and vinculin, we report the existence of adherent membrane patches lacking microfilament bundles and negative for vinculin labelling, but coated with clathrin and identifiable in interference reflection microscopy as less dark than focal adhesions and having dot, U- or sinusoidal shapes.     

Localization of filipin-sterol complexes in cell membranes of eosinophils

The polyene antibiotic filipin was used as a probe for the detection of cholesterol in the cell membranes of eosinophils isolated from the peritoneal exudate of rats. A homogenous distribution of filipin-sterol complexes was observed, both in thin sections and freeze-fracture replicas throughout the whole plasma membrane but not in the membrane of pynocytic vesicles, Golgi complex, endoplasmic reticulum, mitochondria and the nucleus. Few complexes were seen in freeze-fracture replicas showing the membrane of the specific granules. Treatment of living cells with filipin induced aggregation of filipin-sterol complexes at some points of the plasma membrane.