Functional characterization of types of plasma membranes in cerebral cortex

The cerebral cortex of normal oxygenated and of asphyxiated mice has been studied by freeze-fracturing technique with a twofold purpose. First, to investigate changes, if any, in the molecular organization of the plasma membrane of any specific cell type(s) that could be correlated with permeability changes thought to take place as a consequence of asphyxiation. Secondly, to attempt characterization of plasma membranes on the basis of the organization of their fractured faces. The decrease in the extracellular material in asphyxiated cerebral cortex seen in electron micrographs of thin sections could not be correlated with change(s), if any, in the molecular organization of the plasma membrane of any particular cell type. Plasma membranes of various types could be characterized on the basis of the arrangement of particles on the fractured faces. Some of these types correspond to identifiable cell processes, while others have not yet been identified with certainty. Fusion of synaptic vesicles with the presynaptic membrane is mediated through clustering of 100–150 Å membrane-associated particles.     

Freeze-fracture study of Trichomonas vaginalis

The freeze-fracture technique was used to analyse the organization of the plasma membrane, as well as membranes of cytoplasmic organelles, of the pathogenic protozoan Trichomonas vaginalis. Rosettes formed by 4 to 14 intramembranous particles were seen on the fracture faces of the membrane lining the anterior flagella as well as in fracture faces of the plasma membrane enclosing the anterior region of the protozoan and in cytoplasmic organelles. Special organization of the membrane particles were also seen in the region of association of the recurrent flagellum to the cell body.     

Freeze-fracture studies of Cryptosporidium muris.

The attachment site of Cryptosporidium muris to host cells was investigated using the freeze-fracture method. Cryptosporidium muris was enveloped by a double membrane of host plasma membrane origin, which formed the parasitophorous vacuole. The outer membrane of the double membrane was continuous with the host plasma membrane at the dense band, while the inner membrane was connected with the anterior part of the parasite plasma membrane at the annular ring. The density of intramembranous particles (IMP) was dramatically altered at the above two junctures. The outer parasitophorous membrane showed low IMP-density as compared to the host plasma membrane, although both membranes were continuous. The inner parasitophorous membrane had few IMP, whereas the parasite plasma membrane showed numerous IMP. When the attachment sites of parasites and host cells were fractured, circular-shaped fractured faces were observed on both sites of the parasite and host cell. These exposed faces corresponded to the dense bands and were very similar in size in each parasite.     

Structural features of the lateral walls in mammalian cochlear outer hair cells

Summary Freeze-fracture, freeze-etching and thin sections have been used to determine features of the structural organisation of the lateral walls in cochlear outer hair cells. The presence of an organised meshwork of filaments in the lateral cortex of the cell is confirmed in intact unfixed cells. This meshwork showed morphological features similar to the cytoskeletal lattice. The lateral plasma membrane is shown to be protein-rich and to contain cholesterol. The membranes of the subplasmalemmal lateral cisternae contain much less protein, and little cholesterol as judged by their responses to filipin and tomatin. These findings indicate differences in the physical properties of the two membrane systems. On the fracture faces of the plasma membrane there is a high density of intramembrane particles and this particle population is heterogeneous. Some particles show morphological features consistent with those of transmembrane channels. Regularly spaced pillars crossing the space between the plasma and cisternal membranes were identified both in thin sections and in freezeetched preparations, but neither the plasma nor cisternal membrane fracture faces showed any feature corresponding directly to the pillar. This suggests the pillars do not insert directly into either membrane. Freeze-fracture and freeze-etching of unfixed cells indicated that the pillar is indirectly associated with the cytoplasmic surface of the plasma membrane, and, at its inner end, linked to the cortical cytoskeletal lattice on the outer surface of the cisternal membrane.     

A freeze-fracture study on the differentiation of Golgi and plasma membranes in plant cells

Dictyosomes, Golgi vesicles, and plasma membranes were investigated after freeze-fracture in cells from growing root tips of cress (Lepidium sativum L.), that are distinguishable by different cellulose content of the cell wall, into (i) meristematic cells during early formation of the cell plate, (ii) statocytes of the root cap, and (iii) cortex cells of the differentiation zone. The results of this study show that the number of intramembrane particles (imps) is high in dictyosome cisternae, but low in membranes of budding or dictyosome-derived vesicles. Imps are disperse in the vesicle membranes of meristematic cells (i), but are often grouped into clusters in vesicle membranes of statocytes (ii), and of cortex cells (iii). For the number of particle aggregates in vesicle membranes, the following relation holds: (i) < (ii) < (iii). The number of particles on both fracture faces (PF and EF) of the plasma membrane differs widely between the cell types investigated. There are approximately 250, 1400, and 3100 imps microns-2 on the PF and 50, 500, and 300 on the EF of (i), (ii), and (iii), respectively. The structural complexity of the plasma membrane as judged by the degree of particle aggregations on the PF and the number of cellulose microfibrils in the cell wall show the same relationship: (i) < (ii) < (iii). Thus, the strong correlation between the distribution of imps in vesicle membranes, the structural complexity of the plasma membrane, and the content of cellulose microfibrils indicate that selection of imps during vesicle formation at dictyosome cisternae is an integral component of biogenesis and structural differentiation of plant plasma membranes.     

Freeze-fracture electron microscopic studies of age-related plasma membrane changes in Sporothrix schenckii

Characteristics of the plasma membrane of Sporothrix scheckii cells as revealed by freeze-fracture techniques have been classified into eight types (Y1, Y2a, Y2b, Y3a, Y3b, Y4a, Y4b, and Y5) in yeastlike cells grown under the following two conditions: brain heart infusion agar medium at 27 degrees C, and brain heart infusion agar medium at 37 degrees C. Type Y1 cells are yeastlike cells having smooth plasma membranes without any invagination. Typical characteristics of the other types are as follows: type Y2a, smooth plasma membranes with few trenchlike invaginations; type Y2b, wavy plasma membranes with few oval or irregularly formed invaginations; type Y3a, plasma membranes with many randomly distributed trenchlike invaginations; type Y3b, plasma membranes with many cocoonlike or irregularly formed invaginations; type Y4a, plasma membranes with longer trenchlike invaginations; type Y4b, plasma membranes with irregularly formed, enlarged invaginations; and type Y5, smooth or wavy plasma membranes with aggregations of intramembranous particles and with many vacuoles between cell walls and plasma membranes or in the cytoplasm in some cells. By counting the proportion of each type of yeastlike cell under the two conditions and with different cultivation periods, it appears that plasma membrane types change as aging progresses in the following order: type Y1, Y2a, Y3a, Y4a, and Y5 in conidia and type Y1, Y2b, Y3b, Y4b, and Y5 in yeastlike vegetative cells. These observations provide us with an important advantage when studying the effects of antifungal agents on the plasma membrane of Sporothrix scheckii, as it is important to know the natural course of changes in membrane structure during aging.     

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.     

The release of vaccinia virus from infected cells requires RhoA-mDia modulation of cortical actin

Prior to being released from the infected cell, intracellular enveloped vaccinia virus particles are transported from their perinuclear assembly site to the plasma membrane along microtubules by the motor kinesin-1. After fusion with the plasma membrane, stimulation of actin tails beneath extracellular virus particles acts to enhance cell-to-cell virus spread. However, we lack molecular understanding of events that occur at the cell periphery just before and during the liberation of virus particles. Using live cell imaging, we show that virus particles move in the cell cortex, independently of actin tail formation. These cortical movements and the subsequent release of virus particles, which are both actin dependent, require F11L-mediated inhibition of RhoA-mDia signaling. We suggest that the exit of vaccinia virus from infected cells has strong parallels to exocytosis, as it is dependent on the assembly and organization of actin in the cell cortex.     

The Supramolecular Organization of Photosynthetic Membranes of the Thallus Stage of Porphyra leucosticta Thuret. (Bangiales,Rhodophyta) Visualized by Freeze-Fracture

The supramolecular organization of the thylakoid membranes of the thallus stage in the red alga Porphyra leucosticta is studied in replicas of rapidly frozen and fractured cells. Freeze-fractured thylakoid membranes exhibit only two types of fracture faces (EF and PF), because the lamellae in red algal chloroplasts are not stacked. The PF reveals numerous, tightly packed, but randomly distributed particles (density range from 2970 to 3550 particles/μm²). In contrast, the EF particles appear organized into parallel rows, the spacing of which is about 60–70 nm (about 8–9 particles occur along 100 nm of the line that is formed). Significant numbers of single EF particles are randomly distributed between the EF particle rows. The particles on both fracture faces (PF and EF) fall into two size classes: 10 to 11 nm (major size class) and 14 to 15 nm (minor size class).     

Microscopy approaches to investigate protein dynamics and lipid organization

The structure of cell membranes has been intensively investigated and many models and concepts have been proposed for the lateral organization of the plasma membrane. While proteomics and lipidomics have identified many if not all membrane components, how lipids and proteins interactions are coordinated in a specific cell function remains poorly understood. It is generally accepted that the organization of the plasma membrane is likely to play a critical role in the regulation of cell function such as receptor signalling by governing molecular interactions and dynamics. In this review we present different plasma membrane models and discuss microscopy approaches used for investigating protein behaviour, distribution and lipid organization.     

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     

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.     

Close-packing of plasma membrane particles during wall regeneration by isolated higher plant protoplasts—fact or artefact?

Summary Freeze-fracture preparations of protoplasts isolated from cell suspension cultures and leaf mesophyll tissue have been examined by transmission electron microscopy. During the first 72 hours of cell wall regeneration, the 8–10nm intramembraneous particles were randomly distributed on both the protoplasmic and extracellular fracture faces of the plasma membranes of protoplasts frozen and fractured in the culture medium without glutaraldehyde fixation or cryoprotection. Incubation of living protoplasts in culture medium containing 20% v/v glycerol as cryoprotectant prior to freezing without fixation caused deformation of the plasma membrane in the form of protrusions accompanied by particle aggregation on the protoplasmic fracture face of the membrane. Intramembraneous particle aggregation was not observed in protoplasts fixed in glutaraldehyde prior to incubation in medium containing glycerol. The aggregation of particles into hexagonal close packed arrays and elongate chains is discussed in relation to a previous report in the literature of the possible involvement of intramembraneous particle complexes in microfibril formation by isolated higher plant protoplasts.     

Lateral domain diversity in membranes of callus and root cells of potato as revealed by EPR spectroscopy

Lateral heterogeneity in terms of co-existing domains with a distinct molecular organization is an area of increasing interest in membrane biology. The structural and dynamic aspects of the in-plane domain organization of lipids are becoming well documented, especially for model membrane systems. Potato ( Solanum tuberosum L. cv. Desirée) callus cells and roots of plantlets from stem node culture were doped with a spin-labeled analog of the methyl ester of palmitic acid bearing the paramagnetic nitroxide group at position C—5 of the acyl chain, which serves as a monitor of membrane fluidity of the region close to the polar phospholipid head groups of the bilayer. Model reconstruction of the line-shapes of the experimental spectra revealed the co-existence of two types of membrane domains with different ordering and dynamics of lipids in the membranes of both callus and root cells. With changes in temperature, relatively small differences were detected in either type of domain in the lipid ordering of the bilayer as characterized by order parameter S . However, the relative population of domains in the bilayer exhibited stronger temperature dependence. Typically, the relative proportion of disordered domains with less molecular order (smaller S ) was larger in the membranes of callus cells compared to those of root cells, indicating higher fluidity throughout the measured temperature range (5–35°C). The Arrhenius activation energies for rearrangement of lipid molecules within the bilayer were found to be higher for root tissue membranes, indicating the ability of root cells to oppose actively any drastic changes of membrane structuring under temperature stress. The distinctions in organization of lateral domains between the callus and root cell membranes may be correlated with differences in growth rate and metabolic activity between these two types of tissue.     

Dynamic multiple-target tracing to probe spatiotemporal cartography of cell membranes

Although the highly dynamic and mosaic organization of the plasma membrane is well-recognized, depicting a resolved, global view of this organization remains challenging. We present an analytical single-particle tracking (SPT) method and tool, multiple-target tracing (MTT), that takes advantage of the high spatial resolution provided by single-fluorophore sensitivity. MTT can be used to generate dynamic maps at high densities of tracked particles, thereby providing global representation of molecular dynamics in cell membranes. Deflation by subtracting detected peaks allows detection of lower-intensity peaks. We exhaustively detected particles using MTT, with performance reaching theoretical limits, and then reconnected trajectories integrating the statistical information from past trajectories. We demonstrate the potential of this method by applying it to the epidermal growth factor receptor (EGFR) labeled with quantum dots (Qdots), in the plasma membrane of live cells. We anticipate the use of MTT to explore molecular dynamics and interactions at the cell membrane.     

Epidermal growth factor and cyclic AMP stimulation of distinct protein kinase activities in Leydig cell tumor membranes

Epidermal growth factor (EGF) and cyclic AMP were found to stimulate distinct protein kinase activities in plasma membranes prepared from the M5480P murine Leydig cell tumor. EGF stimulated the phosphorylation of two protein bands with apparent molecular weights of 60,000 and 180,000, while cyclic AMP stimulated the phosphorylation of a minor component of molecular weight 220,000. The two types of kinases could also be distinguished on the basis of differential susceptibility to conditions of membrane preparation. These results suggest that EGF stimulates a cyclic AMP-independent protein kinase in murine Leydig cell tumors at the level of the plasma membrane.     

Asymmetric mass distribution of (Na+ + K+)-ATPase in membranes studied by freeze-fracture-etch electron microscopy

SDS-purified porcine kidney (Na+ + K+)-ATPase was studied by thin-section and freeze-etch electron microscopy. Freeze-fracturing of resealed membrane fragments shows no difference in the distribution of intramembranous particles of approx. 9.0 nm in diameter between convex and concave fracture faces. However, two types of convex face are found: FA, which shows a rather smooth background with many intramembranous particles, and FB, which shows a textured background with very few or no intramembranous particles. Etching the fractured samples further reveals that FA faces are covered with many intramembranous particles, while the etched external faces (EA) are either irregularly granulated or reveal many particles half the size of intramembranous particles. FB faces are covered with distinct pits of 9 nm or larger. The etched external surfaces (EB) are covered with many particles of intramembranous particle size. These results suggest that there are two vesicle orientations in our resealed purified membrane preparation: right-side-out, as in vivo, and inside-out. The majority of the protein mass is distributed only on one side of the membranes. Right-side-out resealed membrane vesicles after fracturing and etching show particulated FA convex fracture faces and irregularly granulated or smooth etched EA surfaces, indicating that the FA face is the protoplasmic fracture face and that the majority of the protein mass of the (Na+ + K+)-ATPase is located on the cytoplasmic half of the membrane.     

Membranes of Tetrahymena II. Direct visualization of reversible transitions in biomembrane structure induced by temperature

Rapid temperature changes cause reversible structural transitions in the alveolar membranes of the poikilothermic eukaryote Tetrahymena as revealed by freeze-etch electron microscopy. At an optimal growth temperature of 28°C, 115-Å particles are randomly distributed on the outer faces of the fractured alveolar membranes and apparently corresponding holes are seen on the inner faces. After chilling the cells to 5°C, these particles and holes are largely aggregated. Reheating the cells to 28°C causes a random redistribution of particles and holes. This temperature-induced phenomenon of reversible particle aggregation is discussed with respect to movement of membrane components. We conclude that membrane components move translationally and/or normally to the membrane plane which may be important for transport processes within and across biomembranes.     

Interaction of biological membranes with the cytoskeletal framework of living cells

The review is focused on the molecular structure and function of the proteins composing the actin-based cytokeletal cortex, located at the cytoplasmic face of plasma membranes of eucaryotic cells, which stabilizes integral membrane proteins in separate domains of cell membranes. It includes a survey of the molecular properties of teh proteins of the erythrocyte membrane skeleton such as spectrin, ankyrin, protein 4.1, and adducin. The properties of the immunological counterparts of erythroid cortical proteins found in nonerythroid tissues and cells are compared. The structural organization and function of the newly discovered class of calcium-binding proteins, nonerythroid peripheral membrane proteins, calpactins, are also described. Finally, the discussion of some experimental models illustrates that the membrane skeleton of living cells is actively involved in a wide variety of essential biological functions ranging from differentiation, to maintenance of cell polarity and cell shape, and regulation of exocytotic processes.