DEVELOPMENT AND EVALUATION OF A FREEZE-ETCH,FREEZE-FRACTURE TECHNIQUE APPLIED TO DEVELOPING WHEAT ENDOSPERM

A technique was developed and evaluated whereby differentiating wheat endosperm tissue could be processed for the freeze-etch, freeze-fracture technique without the use of chemical fixatives. Field grown, developing hard red winter wheat (cv. Newton) caryopses were infiltrated with glycerol prior to freezing in liquid nitrogen-cooled Freon-22. Frozen samples were placed in cryogenic vials and stored in liquid nitrogen until needed. Freeze-fracture was carried out under standard conditions. Evaluation of replicas from glycerol-imbibed endosperm was made by comparing them to replicas obtained from freshly frozen untreated endosperm, and endosperm that had been prefixed in glutaraldehyde and paraformaldehyde. Other evaluations were made by comparing replicas of glycerol-treated endosperm to thin sections obtained from wheat that had been imbibed with glycerol, fixed, dehydrated, and infiltrated and embedded in epoxy resin for routine electron microscopy. The results indicate that if the unfixed glycerol-treated wheat endosperm is handled carefully, replicas can be obtained which show few artifacts due to glycerol and freezing. Typical artifacts such as vesiculation of RER, ice crystal damage, production of fusion intermediates, and membrane particle segregation can be nearly eliminated when this technique is applied to developing wheat endosperm.     

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.     

Ultrastructural appearance of red cells frozen with glycerol for clinical use

Freeze-fracture replicas prepared from full units of red cells frozen with glycerol under clinical conditions suggest that the cells are found in a concentrated glycerol phase and so are physically separated from the extracellular ice which formed during freezing. The cells possess a relatively smooth cytoplasmic surface with no evidence of intracellular ice. Half-membrane views of PF faces indicate that the intramembrane particles are aggregated.     

Membrane differentiations in spermatozoa of the squid,Loligo pealeii

Regional differences in the structure of the plasma membrane and acrosome membrane of squid spermatozoa were studied by freeze-fracture and thin section electron microscopy. In regions of close apposition the plasma membrane and acrosome membrane are adjoined to one another by regularly spaced linkages. These linkage sites, overlie a set of fibers located at the inner face of the acrosomal membrane. The acrosomal fibers terminate in a layer of granular material located at the base of the acrosome. Detergent treatment of sperm releases the fibers and granular material as an interconnected complex. Freeze-fracture replicas reveal a random arrangement of intramembranous particles in the plasma membrane over the sperm head and linear aggregates of intramembranous particles in the acrosomal membrane. Several regional differences in the structure of the flagellar plasma membrane are present. The thickness of the glycocalyx is progressively reduced distally along the flagellum. Freeze-fracture replicas show evenly spaced linear arrays of intramembranous particles which extend parallel t o the flagellar long axis. Examination of spermatozoa extracted to disrupt flagellar geometry suggest that the dense fiber-doublet microtubule complexes are attached to the plasma membrane. The possible functional role of these membrane differentiations and their relationship t o membrane structures in mammalian spermatozoa are discussed.     

Membrane fusion during secretion: cortical granule exocytosis in sex urchin eggs as studied by quick-freezing and freeze-fracture

Exocytosis of cortical granules was observed in sea urchin eggs, either quick-frozen or chemically fixed after exposure to sperm. Fertilization produced a wave of exocytosis that began within 20 s and swept across the egg surface in the following 30 s. The front of this wave was marked by fusion of single granules at well-separated sites. Toward the rear of the wave, granule fusion became so abundant that the egg surface left with confluent patches of granule membrane. The resulting redundancy of the egg surface was accommodated by elaboration of characteristic branching microvilli, and by an intense burst of coated vesicle formation at approximately 2 min after insemination. Freeze-fracture replicas of eggs fixed with glutaraldehyde and soaked in glycerol before freezing displayed forms of granule membrane interaction with the plasma membrane which looked like what other investigators have considered to be intermediates in exocytosis. These were small disks of membrane contact or membrane fusion, which often occurred in multiple sites on one granule and also between adjacent granules. However, such membrane interactions were never found in eggs that were quick-frozen fixation, or in eggs fixed and frozen without exposure to glycerol. Glycerination of fixed material appeared to be the important variable; more concentrated glycerol produced a greater abundance of such "intermediates." Thus, these structures may be artifacts produced by dehydrating chemically fixed membranes, and may not be directly relevant to the mechanism by which membranes naturally fuse.     

Freeze-fracture and deep-etching studies on zymogen-granule membranes of the rat pancreas

Summary Whole pancreatic zymogen granules or their membrane fraction were examined by freeze-fracture or deep-etching under different experimental conditions. The granules were fixed for different time periods, or not fixed, and were cryoprotected with glycerol or DMSO; 3% glutaraldehyde followed by 30% glycerol were finally chosen for giving the best resolution and the highest density of intramembrane particles (IMP). IMP are present on the PF and EF leaflets. Their number decreases with the duration of the fixation. Several granules exhibit IMP-free blebs.Incubation of the granules with protamine sulfate causes an aggregation of IMP and of the rough-textured background on the EF leaflet. A second fracture plane can be formed and has been shown by deep-etching to be intercalated between PF and EF. Deep-etching has also shown that particles attached to the perimeter of the granules and of the blebs are, in fact, large nodules on the PS face which partially extend onto the blebs and do not aggregate with the IMP after protamine treatment. Fusion is also indicated between membrane vesicles. Freeze-fracture of the purified membrane fraction seems to indicate the formation of an IMP cap during the lysis of the granule. Moreover, large nodules remain present on the PS face on these membrane fractions but the majority disappear after washing at pH 11.2 with Na₂CO₃ and EDTA.Supported by a research grant from the Medical Research Council of Canada (F.L.) (J.S.H.)     

A freeze-fracture study of afferent and efferent synapses of hair cells in the sensory epithelium of the organ of Corti in the guinea pig

Summary Afferent and efferent synapses of hair cells in the organ of Corti of the guinea pig have been examined in freeze-fracture replicas.Afferent synapse In the inner hair cells, intramembranous particles 10 nm in diameter are aggregated on the ridge on the P-face of the presynaptic membrane directly beneath the synaptic rod. In the outer hair cells, in which the synaptic rod is located in the presynaptic cytoplasm underneath the presynaptic membrane, small aggregations of intramembranous particles 10 nm in diameter can be found on the P-face of the presynaptic membrane corresponding to the site of the presynaptic dense projection. Intramembranous particles 10 nm in diameter are also densely aggregated on the P-face of the postsynaptic membrane of the outer hair cells.Efferent synapse of the outer hair cells Large intramembranous particles 13 nm in diameter are distributed in clusters composed of four to ten particles on the P-face of the presynaptic membrane. In the P-face of the postsynaptic membrane, disc-like aggregations of intramembranous particles 9 nm in diameter are found. The subsynaptic cistern covers the cytoplasmic surface of the postsynaptic membrane of the efferent synapse; it may cover more than one postsynaptic membrane when several efferent synapses are in close proximity to one another.     

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.     

Morphological changes during conoid extrusion in Toxoplasma gondii tachyzoites treated with calcium ionophore

Treatment of tachyzoites of Toxoplasma gondii with the calcium ionophore A23187 induced dramatic ultrastructural changes that were observed by light and electron microscopy. Light microscopy showed a higher percentage (22%) of tachyzoites with the conoid extruded when compared to control parasites. Electron microscopy confirmed the conoid extrusion by both transmission and scanning electron microscopy. Freeze-fracture replicas showed that the plasma membrane adjacent to cytoplasmic dense granules appeared devoid of intramembranous particles. Membrane-limited vesicles and filopodium-like structures at the cell surface were observed in treated cells. 3-D reconstruction from serial sections confirmed the data and showed a heterogeneity in dense granule shape not reported in control cells.     

Cytochemistry and freeze-fracture of membranes isolated from the electrocyte of Electrophorus electricus (L.)

Summary Membranes were isolated from the main electric organ of Electrophorus electricus and studied by means of cytochemistry and freezefracture. The membrane fractions consisted of vesicles inside-in as determined by localization of anionic sites using colloidal iron and cationized ferritin particles. The anionic sites were not homogeneously distributed on the surface of the vesicle. Freeze-fracture showed the presence of intramembranous particles associated with either protoplasmic (P) or extracellular (E) faces of the membrane. Regions of the membrane without particles were observed. The results are discussed in relation to the existence of association between intramembranous particles and membrane receptors.For all correspondence     

Modulation of the distribution of plasma membrane intramembranous particles in contact-inhibited and transformed cells.

The intrinsic organization of the plasma membrane differs in normal and transformed cells. With the technique of freeze fracture and electron microscopy contact inhibited 3T3 cells have been shown to contain aggregated plasma membrane intramembranous particles, while transformed cells demonstrate a uniform particle distribution. The distribution of intramembrous particles in transformed cells can be affected by colchicine or vinblastine which induces a dose- and time-dependent particle aggregation. These observations suggest that microtubules and other membrane-associated colchicine-sensitive proteins probably influence the distribution of intrinsic membrane proteins and intramembranous particles in nucleated mammalian cells. An aggregated particle distribution has been observed in 3T3 cells or colchicine-treated transformed cells frozen in media, phosphate-buffered saline or following brief exposure to glycerol, sucrose or dimethyl sulfoxide containing solutions, independent of whether specimens were rapidly frozen from 37 degrees C, room temperature or 4 degrees C incubations. Cells briefly stabilized in 1% formaldehyde yields similar patterns of particle distribution as cells rapidly frozen in media or cryoprotectants. Glutaraldehyde fixation of cells, however, appears to alter the fracturing process in these cells, as visualized by an altered fracture face appearance, decreased numbers of particles, and no particle aggregates. Differences in membrane organization between normal and transformed cells have therefore been demonstrated using a series of preparative methods and colchicine and vinblastine have been shown to modulate intramembranous particle distribution in transformed 3T3 cells.     

Tannic acid improves the visualization of the human erythrocyte membrane skeleton by freeze-etching

The effect of fixatives on the membrane skeleton underlying the human erythrocyte membrane was examined by freeze-etching. An anastomosing fibrillar network was readily observed on the protoplasmic surface of the erythrocyte membrane treated with tannic acid. Such structure was much less defined in unfixed membrane or membrane fixed with glutaraldehyde or glutaraldehyde followed by osmium tetraoxide. Tannic acid caused a marked increase in diameter of the fibrillar components of the membrane skeleton and of the protoplasmic surface particles of inside-out vesicles prepared by alkali treatment but did not affect the size of intramembranous particles seen on fracture faces nor the appearance of exoplasmic surfaces. The improved visualization of the membrane skeleton after treatment with tannic acid resulted from interactions between tannic acid and exposed membrane proteins.     

Membrane particle arrays associated with the basal body and with contractile vacuole secretion in Chlamydomonas

Freeze-fracture replicas reveal that five distinct types of intramembranous particle arrays coexist within a small sector of the C. reinhardtii cell flagellar membrane. Of these, three are newly described in this report. (a) Flagellar bracelets, which encircle the flagellar bases, appear to be intrinsically ordered strands of particles of unknown function. (b) Strut arrays, representing nine sites where the basal body attaches to the membrane, appear to serve a mechanical function. (c) Contractile vacuole arrays, which develop into circular plaques of particles, appear to serve as "membrane gates" through which water is discharged from the cell.     

The influence of high pressure freezing on mammalian nerve tissue

Summary Vitrification of biological specimens in liquid nitrogen can be achieved under high pressure (2,100 bars). This procedure obviates the use of aldehyde fixation and cryoprotection (glycerol). The present work demonstrates its applicability to the freeze-etching of mammalian brain tissue. Freeze-fracture replicas from rat cerebellar cortex and subfornical organ prepared by this method are compared to conventionally processed material using aldehyde fixation, glycerination and freezing with Freon. The formation of large ice crystals is prevented in tissue blocks up to 0.5 mm thick; deep etching is markedly enhanced. Cytoplasmic microstructures such as mitochondrial cristae, microtubules and microfilaments, are readily observable against a finely granulated cytosol matrix. An additional advantage is the combined application with freeze-substitution.     

Freeze-fracture analysis of gap junction disruption in rat ovarian granulosa cells

The effects of chemical dissociation on rat ovarian granulosa cell gap junctions has been studied using freeze-fracture electron microscopy. Sequential exposure of granulosa cells within follicles to solutions containing 6·8 mM EGTA [ethylene-bis-(β-aminoethyl ether)-N,N′-tetra acetic acid] and 0·5 M sucrose results in extensive cellular dissociation of the follicular epithelium. Freeze-fracture replicas made from fixed, control or EGTA-treated ovarian follicles exhibit extensive gap junctions between granulosa cells that are characterized by a range of packing order of constituent P-face particles or E-face pits. In contrast, exposure to 0·5 M sucrose containing 1·8 mM EGTA for as little as 1 min results in a consistently close packing of particles or pits which is accompanied by splitting of gap junctions between granulosa cells. The process of junction splitting was studied in detail in replicas prepared from follicles treated sequentially for various periods of time with EGTA and sucrose solutions. Initially, large gap junctions lose their regular shape and fragment into numerous tightly packed aggregates of P-face particles or E-face pits which are separated by unspecialized areas of plasma membrane. Subsequent to junction fragmentation, individual junction plaques separate at sites of cell contact and generate hemijunctions that border the intercellular space, Hemijunctions undergo particle dispersion of the P fracture face which results in an increased density of large intramembrane particles; no corresponding change in E-face pits is discernible at this stage. Morphometric analysis of replicas of tissue undergoing junction splitting indicates that junctional surface area decreases to 10–20% of control levels during this same treatment and so further supports the qualitative observations on junction fragmentation. Viabilities of granulosa cells obtained by these techniques also agree with the sequence observed in the morphometric analysis of the replicas. Finally, within 15 min after placing ovaries in isotonic, Ca²⁺-containing salt solutions, gap junction reformation occurs by aggregation of particles at sites of intercellular contact. These sites are distinguished by the appearance of short surface protrusions or indentations on their respective P and E fracture faces. The data suggest a mechanism for EGTA-sucrose mediated cellular dissociation in the follicular epithelium in which gap junctional particles are free to move in the plane of the plasma membrane and may be re-utilized to form gap junctions in the presence of extracellular calcium.     

The distribution of orthogonal assemblies and other intercalated particles in frog sartorius and rabbit sacrospinalis muscle.

Freeze-fracture replicas have been prepared from two fast-acting vertebrate muscles (frog sartorius and rabbit sacrospinalis) and are described with particular reference to the distribution of intercalated particles in the plasma membrane. T-tubule and SR cisternae. Orthogonal assemblies of small particles are present on the A face plasma membrane in each instance, and their distribution (in sartorius) is found to be random with respect to the underlying myofibrillar sarcomere repeat. Such assemblies are not present on A or B faces of T-tubule or SR cisternae. Asymmetric particle distribution is described for fracture faces of the T-tubules and SR: the profuse particle packing of the SR A face is uniform from terminal cisternae to medial fenestrated collar. Intercalated particles are present on A and B faces of T-tubule fractures; more commonly on the latter. These results are compared with studies on insect muscles, and a comparative approach to further studies on the correlation between membrane structure and function is discussed.     

Fusion of phospholipid vesicles arrested by quick-freezing. The question of lipidic particles as intermediates in membrane fusion

We have examined the early events in Ca²⁺-induced fusion of large (0.2 μm diameter) unilamellar cardiolipin/phosphatidylcholine and phosphatidylserine/phosphatidylethanolamine vesicles by quick-freezing freeze-fracture electron microscopy, eliminating the necessity of using glycerol as a cryoprotectant. Freeze-fracture replicas of vesicle suspensions frozen after 1–2 s of stimulation revealed that the majority of vesicles had already undergone membrane fusion, as evidenced by dumbbell-shaped structures and large vesicles. In the absence of glycerol, lipidic particles or the hexagonal H_II phase, which have been proposed to be intermediate structures in membrane fusion, were not observed at the sites of fusion. Lipidic particles were evident in less than 5% of the cardiolipin/phosphatidylcholine vesicles after long-term incubation with Ca²⁺, and the addition of glycerol produced more vesicles displaying the particles. We have also shown that rapid fusion occurred within seconds of Ca²⁺ addition by the time-course of fluorescence emission produced by the intermixing of aqueous contents of two separate vesicle populations. These studies therefore have produced no evidence that lipidic particles are necessary intermediates for membrane fusion. On the contrary, they indicate that lipidic particles are structures obtained at equilibrium long after fusion has occurred and they become particularly prevalent in the presence of glycerol.     

Fine structures of sponge cell membranes: comparative study with freeze-fracture and conventional thin section methods

Freeze-fracture replicas of sponge cell membranes revealed in general a low density of intramembranous particles, with the exceptions of the membrane (silicalemma) surrounding the siliceous spicules in Ephydatia and the membranes of spherulous cells in Chondrosia. In addition, several types of particle arrangements were observed. A classical necklace is present at the base of the choanocyte flagellum. Rosettes of particles are particularly obvious in the apical membranes of choanocytes, where they are associated with the fuzzy coat covering these cells. Parallel ridges of particles were observed along the microvilli of the choanocyte collar, at sites of insertion of connecting filaments. Rows of particles were observed in the plasma membrane of pinacocytes in Ephydatia where they are located on areas deformed by protruding fibrillar inclusions. Pinacocyte plasma membranes in this species also can contain accumulations of particles which are likely related to desmosomes. Single rows of aligned particles and double rows of staggered particles (sometimes organized in large plates) in addition to rhombic particle arrays were encountered on replicas of marine sponge cell membranes. No classical arrangements corresponding to gap junctions, tight junctions or septate desmosomes were observed. The significance of these data is analysed.     

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.     

Localization of Filipin-Sterol Complexes in the Membranes of Beta vulgaris Roots and Spinacia oleracea Chloroplasts

Filipin was used as a cytochemical probe for membrane sterols in the root storage tissue of the red beet Beta vulgaris L. and the chloroplasts of Spinacia oleracea L. In unfixed beet tissue, filipin lysed the cells. Freeze-fracture replicas revealed that the filipin-sterol complexes were tightly aggregated in the plasma membrane, while in thin section the complexes corrugated the plasma membrane. If the cells were fixed with glutaraldehyde prior to the filipin treatment, the cell structure was preserved. Filipin-induced lesions were dispersed or clustered loosely in the plasma membrane. A few filipin-sterol complexes were observed in the tonoplast. In spinach chloroplasts, filipin-sterol complexes were limited to the outer membrane of the envelope and were not found in the inner membrane of the envelope or in the lamellar membranes. If the filipin-sterol complexes accurately mapped the distribution of membrane sterols, then sterol was located predominantly in the plasma membrane of the red beet and in the outer membrane of the chloroplast envelope. Furthermore, the sterol may be heterogenously distributed laterally in both these membranes.