Rotary-Shadowed Freeze-Fracture Replicas: A Simple Method for the Analysis of Fracture Faces

In rotary-shadowed freeze-fracture replicas, intramembrane particles on the periphery of a membrane fracture face are not uniformly shadowed from all sides. Those eccentrically positioned intramembrane particles with a net centripetally directed shadowing are on a convex fracture face. In contrast, those eccentrically positioned intramembrane particles with a net centrifugally directed shadowing are on a concave fracture face. Centrally positioned intramembrane particles on convex faces are uniformly shadowed from all sides; however, central depressions of concave faces are often unshadowed.     

Morphology of proteoliposomes reconstituted with purified lac carrier protein from Escherichia coli

Proteoliposomes reconstituted with purified lac carrier protein from Escherichia coli were ultra-rapidly frozen and examined by freeze-fracture-etch electron microscopy. The proteoliposomes are greater than 95% unilamellar, and the majority are 30-150 nm in diameter. Fracture faces of proteoliposomes (at a protein:lipid molecular ratio of about 1:2500) display 7.0-nm diameter globular intramembrane particles uniformly distributed on convex and concave surfaces. Calculations of particle composition suggest that each intramembrane particle probably contains one or two molecules of the 46.5-kDa transmembranous lac carrier protein, depending on the correction factor for the thickness of the metal deposited to form the platinum/carbon replicas. Etched surfaces of the proteoliposomes are smooth. Incubation of the proteoliposomes with monoclonal antibody 4B1, which binds to an epitope in the lac carrier on the exterior of the proteoliposomes, dramatically alters the intramembrane particle distribution. After incubation with antibody, the convex (inner monolayer) fracture faces are nearly devoid of intramembrane particles, and an overall 4-fold reduction in the total number of intramembrane particles is observed.     

Characterization of (Na+ + K+)-ATPase liposomes. II. Effect of alpha-subunit digestion on intramembrane particle formation and Na+,K+-transport

The effect of the protein structure of (Na+ + K+)-ATPase on its incorporation into liposome membranes was investigated as follows: the catalytic alpha-subunit of (Na+ + K+)-ATPase was split into low-molecular weight fragments by trypsin treatment and the digested enzyme was reconstituted at the same protein concentration as intact control enzyme. The reconstitution process was quantified by the average number of intramembrane particles appearing on concave and convex fracture faces after freeze-fracture of the (Na+ + K+)-ATPase liposomes. The number of intramembrane particles as well as their distribution on concave and convex fracture faces is not modified by the proteolysis. In contrast, the ATPase activity and the transport capacity of the (Na+ + K+)-ATPase decrease progressively with increasing incubation times in the presence of trypsin and are abolished when the original 100 000 molecular weight alpha-subunit is no longer visible by sodium dodecylsulfate gel electrophoresis. Apparently, functional (Na+ + K+)-ATPase with intact protein structure and digested, non functional enzyme consisting of fragments of the alpha-subunit reconstitute in the same manner and to the same extent as judged by freeze-fracture analysis. We conclude that, while trypsin treatment modifies the (Na+ + K+)-ATPase molecule in a functional sense, it appears not to modify its interaction with the bilayer in producing intramembrane particles. On the basis of our results, we propose a lipid-lipid interaction mechanism for reconstitution of (Na+ + K+)-ATPase.     

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.     

Demonstration of rare protein in the outer membrane of Treponema pallidum subsp. pallidum by freeze-fracture analysis.

The surface of Treponema pallidum subsp. pallidum (T. pallidum), the etiologic agent of syphilis, appears antigenically inert and lacks detectable protein, as judged by immunocytochemical and biochemical techniques commonly used to identify the outer membrane (OM) constituents of gram-negative bacteria. We examined T. pallidum by freeze-fracture electron microscopy to visualize the architecture of its OM. Treponema phagedenis biotype Reiter (T. phagedenis Reiter), a nonpathogenic host-associated treponeme, and Spirochaeta aurantia, a free-living spirochete, were studied similarly. Few intramembranous particles interrupted the smooth convex and concave fracture faces of the OM of T. pallidum, demonstrating that the OM of this organism is an unusual, nearly naked lipid bilayer. In contrast, the concave fracture face of the OM of S. aurantia was densely covered with particles, indicating the presence of abundant integral membrane proteins, a feature shared by typical gram-negative organisms. The concentration of particles in the OM concave fracture face of T. phagedenis Reiter was intermediate between those of T. pallidum and S. aurantia. Similar to typical gram-negative bacteria, the OM convex fracture faces of the three spirochetes contained relatively few particles. The unique molecular architecture of the OM of T. pallidum can explain the puzzling in vitro properties of the surface of the organism and may reflect a specific adaptation by which treponemes evade the host immune response.     

Analysis of outer membrane ultrastructure of pathogenic Treponema and Borrelia species by freeze-fracture electron microscopy.

We analyzed the outer membrane (OM) ultrastructure of four pathogenic members of the family Spirochaetaceae by freeze fracture. The OM of Treponema pallidum subsp. pertenue contained a low intramembranous particle concentration, indicating that it contains few OM transmembrane proteins. The concave OM fracture faces of Treponema hyodysenteriae and Borrelia burgdorferi contained dense populations of particles, typical of gram-negative organisms. A relatively low concentration of particles which were evenly divided between a small and a large species was present in the concave OM fracture face of Borrelia hermsii; the convex OM fracture face contained only small particles. As for gram-negative bacteria, the convex OM fracture face particle concentrations of these pathogens were low. These spirochetes cleaved preferentially within the OM, in contrast to typical gram-negative bacteria, which tend to fracture within the inner membrane. The OM ultrastructure of T. pallidum subsp. pertenue provides an explanation for the lack of antigenicity of the treponemal surface and may reflect a mechanism by which this pathogen evades the host immune response.     

Freeze-fracture study of rat liver peroxisomes: evidence for an induction of intramembrane particles by agents stimulating peroxisomal proliferation

The membrane ultrastructure of isolated rat liver peroxisomes has been observed by rapid freezing and freeze-fracture techniques. Unidirectional and rotary shadowing allows a clear visualization of the intramembrane particles (IMPs) on both the protoplasmic fracture (PF) leaflet and the endoplasmic fracture (EF) leaflet and reveals an asymmetric distribution of IMPs. Both fracture faces were uniformly studded by IMPs, and the frequency was about seven times higher on the P face (2322 per 1.0 micron2) than on the E face (322 per 1.0 micron2). Administration of the peroxisomal proliferator clofibrate (ethyl-p-chlorophenoxyisobutyrate) induced a marked increase in the frequency of IMPs on both the P face (2.2-fold) and the E face (1.7-fold). The average size decreased (P less than 0.001) from 45.7 +/- 16.5 nm2 to 35.2 +/- 10.8 nm2 on the P face. A similar increase in the frequency of IMPs was observed on the P face (1.8-fold) and the E face (1.8-fold) of peroxisomes from rats fed a semisynthetic diet containing 20% (w/w) of partially hydrogenated fish oil. The average size increased (P less than 0.001) from 36.6 +/- 19.7 to 50.0 +/- 23.5 nm2 on the E face. This study demonstrates alterations both in frequency and size distribution of IMPs in liver peroxisomal membranes on exposure of rats to agents known to induce peroxisomal proliferation. The increase in frequency of IMPs was as expected from the observed increase in one of the major integral membrane polypeptides, with apparent molecular mass of 69 (or 70) kDa, in proliferating rat liver peroxisomes.     

Ultrastructural analysis of the freeze-etched spore envelope of the microsporidian,Nosema apis zander

The outer limiting layer of the spore coat ofNosema apis is relatively smooth. The inner limiting layer shows two fractured faces, the concave face carrying many stud-like projections, 120 nm long and 50 nm high, while the convex face carries numerous depressions which are complementary to the projections. In addition, the convex face bears 7 nm particles. In between the outer and inner limiting layers lies the thick homogeneous portion of spore coat which is comprised of numerous microfibres, each 9 nm in diameter. These microfibres resemble those in the freeze-etched host endocuticle. Next to the inner limiting layer of the spore coat are double spore membranes. The convex faces of these spore membranes have a dense population of particles, each 7 nm in diameter.     

Electron microscopy of Bacillus subtilis protoplast membrane after treatment with phospholipase A2 and phospholipase C

The effects of phospholipase A₂ and phospholipase C on Bacillus subtilis protoplast membrane have been studied by electron microscopy and by chemical methods. Phospholipase A₂ (from porcine pancreas) almost quantitatively converted cardiolipin, phosphatidylethanolamine, phosphatidylglycerol and lysylphosphatidylglycerol to fatty acids and lysoderivatives. The fatty acids like the lysophospholipids remained in the membrane. Phospholipase C (from Bacillus cereus) hydrolyzed about 80% of the phosphatidylethanolamine and about 40% of the cardiolipin. Electron microscopy has been carried out with respect to general morphology of the affected protoplasts, the occurrence of a triple-layered membrane structure in thin sections, and the ultrastructure of membrane fracture faces upon freeze fracturing. Phospholipase A₂ treatment resulted in fragmentation of the protoplasts. In all cases the triple-layered membrane profile was preserved in thin sections. The membrane fracture faces appeared normal, i.e. they showed a convex face with many particles and a concave face with few particles. This indicated that the hydrophobic interior of the membrane was not too much damaged after incubation with phospholipases, presumably because of the stabilizing action of membrane proteins.     

Quantitative characterization of a biological membrane by means of its spatial autocovariance.

Profiles for the exoplasmic face (EF) of the freeze-fractured plasma membrane from the root storage tissue of red beets are reconstructed by microdensitometry of micrographs of surface-shadowed-platinum carbon replicas. Autocovariance functions (ACFs) are computed from those profiles. The initial portions of the ACFs have a Gaussian form whose parameters (root mean square surface roughness and autocovariance length) are estimated. The parameter estimates are used to show that the pits on the EF faces are in good complementarity with the intramembrane particles seen on the complementary protoplasmic fracture faces.     

Intercellular junctions of antennal gland epithelial cells in the crayfish,Orconectes virilis

Summary Labyrinth and nephridial canal cells of the crayfish (Orconectes virilis) antennal gland possess two types of intercellular junctions revealed by freeze-fracture studies. Apical margins of the cells are connected by long septate junctions. In replicas, these junctions consist of many parallel rows of 80–140 Å intramembrane particles situated on the PF membrane face (EF and PF fracture faces of Branton et al., 1975). Rows of pits are found on the EF fracture face and are deemed complementary to the rows of particles. Moreover, lateral margins of basal regions of the epithelial cells are attached by many intercellular junctions. These contacts are characterized in thin plastic sections by a narrow dense cytoplasmic plaque located subjacent to the plasma membrane at sites of adjoined cells, and 5 to 12 fine strands of dense material that extend across the intercellular gap between adjoined cells. In freeze-fracture replicas, EF intramembrane faces basal to the region of the plasma membrane containing septate junctions exhibit numerous discoid clusters of particles. The particle aggregates, assumed to represent freeze-cleave images of adhering junctions, range from 900 to 3,700 Å in diameter, with individual particles about 185 Å in diameter. These junctions appear to connect epithelial cell processes formed by basal infoldings of the plasma-lemma, and occur between adjacent cells as well as adjacent processes of a single cell. The discrete aggregates of particles resemble replicated desmosomes (Shienvold and Kelly, 1974) and hemi-desmosomes (Shivers, 1976); therefore, they probably do not constitute a basis for electrical coupling between antennal gland epithelial cells.Supported by the National Research Council of Canada     

Membrane structures ofAcholeplasma laidlawii and its virus

The main types of ultrastructures found in the freeze-fracture faces ofAcholeplasma laidlawii S 2 and its virus MV-Lg-L 172 were (1) particles 7–19 nm in diameter, mostly located in the convex cytoplasmic fracture faces. (2) small bulges or aggregates, 13–25 nm in diameter. which occupied only limited areas of both inner and outer fracture faces of some mycoplasmas, (3) numerous tiny grains and/or spikes 2–6 nm in diameter, protruding from a finely structured background, especially in the outer concave mycoplasmal fracture faces, and (4) linear structures, most probably fibrils and thicker filaments, both in the fracture faces and around mycoplasmas and viruses and connected with them. There was a high degree of structural similarity between mycoplasmal and viral membranes; no obvious significant difference was found.     

A COMPLEMENTARY FREEZE-FRACTURE STUDY OF CHRYSOCHROMULINA CHITON (HAPTOPHYCEAE)

Complementary freeze-fracture replicas and high resolution tantalum-tungsten shadowing have been used in a study of the membanes of the marine alga Chrysochromulina chiton. Membrane particle populations range from 38/100 nm² in the plastid to 2/100 nm² in the pyrenoid cap membrane. Membrane asymmetry was evident in all membranes, but was most obvious in those with higher particle numbers. In all complementary replica pairs, particles were always more numerous on protoplasmic fracture faces. Small, particle-free areas with bordering particles were also seen as recurring membrane features. Complementarity of matching fracture faces was seen for very small background granularity patterns and for large membrane components, but not for particles. Complementarity can also be seen in non-membranous fracture faces both within and external to the cell, suggesting the presence of polymeric materials in these areas that produce “particles” due to plastic deformation.     

Structural similarity of the membrane envelopes of rhizobial bacteroids and the host plasma membrane as revealed by freeze-fracturing.

The freeze-fracture technique was used to study the host plasma membrane and the membrane envelope of bacteroids in rhizobial root nodules of three host-rhizobium combinations. In all three combinations studied, the membrane envelopes of bacteroids are structurally similar to their host plasma membrane. However, the membrane appears to be reversed, because the number and arrangement of particles in the outer fractured face (face A, concave) and in the inner fractured face (face B, convex) of the host plasma membrane are seen, respectively, in the inner fractured face (face B, convex) and in the outer fractured face (face A, concave) of the membrane envelope of the bacteroids at an early stage. This reversion of the membrane surface is consistent with the hypothesis that the membrane envelopes of bacteroids are derived from the host plasma membrane during endocytotic engulfment.     

Membrane structure of caveolae and isolated caveolin-rich vesicles

 Caveolae are specialized invaginated domains of the plasma membrane. Using freeze-fracture electron microscopy, the shape of caveolae and the distribution of intramembrane particles (integral membrane proteins) were analyzed. The caveolar membrane is highly curved and forms flask-like invaginations with a diameter of 80–120 nm with an open porus of 30–50 nm in diameter. The fracture faces of caveolar membranes are nearly free of intramembrane particles. Protein particles in a circular arrangement surrounding the caveolar opening were found on plasma membrane fracture faces. For isolation of caveolin-enriched membrane vesicles, the method of Triton X-100 solubilization, as well as a detergent-free isolation method, was used. The caveolin-rich vesicles had an average size of between 100 and 200 nm. No striated coat could be detected on the surface of isolated caveolin-rich vesicles. Areas of clustered intramembrane particles were found frequently on membrane fracture faces of caveolin-rich vesicles. The shape of these membrane protein clusters is often ring-like with a diameter of 30–50 nm. Membrane openings were found to be present in the caveolin-rich membrane vesicles, mostly localized in the areas of the clustered membrane proteins. Immunogold labeling of caveolin showed that the protein is a component within the membrane protein clusters and is not randomly distributed on the membrane of caveolin-rich vesicles. Accepted: 16 September 1998     

Fracture Faces in the Cell Envelope of Escherichia coli

Freeze-fracturing of Escherichia coli cells in the presence of 30% (v/v) glycerol resulted in a double cleavage of the cell envelope exposing two convex and two concave fracture faces ([Formula: see text], [Formula: see text] and [Formula: see text], [Formula: see text]) with characteristic patterns. Complementary replicas revealed the relationship of the fracture faces to their corresponding fracture planes. The inner fracture plane splits the plasma membrane at one particular level. Apparently the outer fracture plane was located in the outer part of the wall, as it was separated by a layer ([Formula: see text]) from the fractured profile (CW1) presumably corresponding to the murein layer. The outer fracture plane did alternate toward the cell periphery, exposing complementary smooth areas ([Formula: see text] and [Formula: see text]). When cells were freeze-fractured in the absence of glycerol, the outer cell surface appeared as an etching face rather than a fracture face. A schematic representation of the relative location of the different fracture faces in the E. coli cell envelope is given.     

Ultrastructural and chemical analysis of the outer membrane leaflet of the human red blood cell

Structural and biochemical analysis of the outer membrane leaflet of human erythrocytes freeze-fractured on positively charged supports showed that glycophorin A is its major constituent. Two classes of intramembrane particles can be discriminated on the external fracture face: those which are high but small in diameter and those which are low and large or elongated. The presence of small amount of band 3 protein in the outer membrane leaflet cannot be ruled out; it could be contained in the class of 'high' intramembrane particles on the external fracture face.     

Decoration of specific sites on freeze-fractured membranes

Fracturing under ultrahigh vacuum (UHV, P less than or equal to 10(-9) Torr) produces membrane fracture faces devoid of contamination. Such clean surfaces are a prerequisite for studies of interactions between condensing gases and distinct regions of a surface. For the study of water condensation, a device has been developed which enables production of pure water vapor and controlled variation of its partial pressure in an UHV freeze-fracture apparatus. Experiments with yeast plasmalemma fracture faces, produced at -196 degrees C and exposed to pure water vapor before replication, resulted in a "specific decoration" with ice crystals of those pits in the extraplasmic face where the corresponding particles of the plasmic face had been removed. Because water condenses as discrete ice crystals which resemble intramembrane particles, ice crystals might easily be misinterpreted as actual membrane structures. At low specimen temperature (T less than or equal to 110 degrees C) the structural features of membrane fracture faces produced under high vacuum (P approximately 10(-6) Torr) should, therefore, be interpreted with caution.     

A model for de novo synthesis and assembly of tight intercellular junctions. Ultrastructural correlates and experimental verification of the model revealed by freeze-fracture

The structure and function of intercellular tight (occluding) junctions, which constitute the anatomical basis for highly regulated interfaces between tissue compartments such as the blood-testis and blood-brain barriers, are well known. Details of the synthesis and assembly of tight junctions, however, have been difficult to determine primarily because no model for study of these processes has been recognized. Primary cultures of brain capillary endothelial cells are proposed as a model in which events of the synthesis and assembly of tight junctions can be examined by monitoring morphological features of each step in freeze-fracture replicas of the endothelial cell plasma membrane. Examination of replicas of non-confluent monolayers of endothelial cells reveals the following intramembrane structures proposed as 'markers' for the sequential events of synthesis and assembly of zonulae occludentes: development of surface contours consisting of elongate terraces and furrows (valleys) orientated parallel to the axis of cytoplasmic extensions of spreading endothelial cells, appearance of small circular PF face depressions (or volcano-like protrusions on the EF face) that represent cytoplasmic vesicle-plasma membrane fusion sites, which are positioned in linear arrays along the contour furrows, appearance of 13-15 nm intramembrane particles at the perimeter of the vesicle fusion sites, and alignment of these intramembrane particles into the long, parallel, anastomosed strands characteristic of mature tight junctions. These structural features of brain endothelial cells in monolayer culture constitute the morphological expression of: reshaping the cell surface to align future junction-containing regions with those of adjacent cells, delivery and insertion of newly synthesized junctional intramembrane particles into regions of the plasma membrane where tight junctions will form, and aggregation and alignment of tight junction intramembrane particles into the complex interconnected strands of mature zonulae occludentes. The distribution of filipin-sterol complex-free regions on the PF intramembrane fracture face of junction-forming endothelial plasmalemmae corresponds precisely to the furrows, aligned vesicle fusion sites and anastomosed strands of tight junctional elements.(ABSTRACT TRUNCATED AT 400 WORDS)     

Freeze-fracture study of the zymogen granule membrane of pancreas: two novel types of intramembrane particles

The ultrastructure of the zymogen granule (ZG) membrane has been observed in vitro by rapid freezing and freeze-fracture techniques. Unidirectional shadowing of the plasmic fracture (PF) leaflet of the intact granule reveals a relatively smooth surface uniformly studded by intramembrane particles (IMP; 360 microns2) their diameters ranging from 5 to 18 nm (mean = 10.2 nm) but does not allow a clear visualization of the particles on the external fracture (EF) leaflet. Indeed, rotary shadowing reveals that the EF leaflet presents a highly textured subparticle background with a significantly lower frequency of IMP (44 microns2) showing diameters from 9 to 18 nm and a shift to larger IMP (mean = 12.3 nm). Two hitherto undescribed types of IMP are found on both leaflets of the membrane: first a population of 13-nm particles with an electron-lucent center or "pore", the most frequent type on the EF face (26%), is a second population of large IMP (15 nm) characterized by a large "pore" (5.0 nm diameter) subdivided by a delicate cross-shaped structure. In alkaline conditions, pH 8.2, ZG lysis occurs rapidly and membrane ghosts thus obtained were rapidly frozen or suspended in dextran and filtered immediately. Transmission electron microscopy (TEM) shows many opened ghosts with adhering amorphous material and numerous small vesicles near or still attached to openings in the ghosts. Freeze-fracture preparations show that granule lysis is accompanied by major alterations of membrane ultrastructure; the subparticle background on the EF leaflet is now visible only as a cap or linear crest at one pole of the ghosts. These two newly formed zones are demarcated by a row of 13-nm particles, whereas the other IMP are confined to the subparticle background. Some images suggest that the subparticle background and 13-nm IMP necklace give rise to vesicles, some of them occasionally attached to the ghosts. The subparticle background on the EF leaflet shows a complementary imprint on the PF leaflet which is similarly modified. This study shows the presence of hitherto undescribed types of IMP and also demonstrates alterations of certain domains of zymogen granule membranes that occur at the moment of lysis, associated with a redistribution of different particle populations.