Secretory surface phenomena in freeze-etched preparations of the adenohypophysical cells and neurosecretory fibers

Summary The freeze-etching technique was used in studies of cell surface phenomena during the release of secretory products from the adenohypophysis and from neurosecretory terminals of rats in which exocytosis had been stimulated by the administration of hypothalamic extracts (somatotrophs, thyrotrophs, gonadotrophs and mammotrophs) or severe hemorrhage (neurohypophysis). The observations suggest that secretory granules are extruded through an opening at the tip of a protrusion of the cellular surface. The protrusions seem to result from the abutting of secretory granules on the inner surface of the plasma membrane. These structural details revealed in freeze-etched preparations have not been seen previously in conventional micrographs of ultrathin sections and may provide a clue to the mechanism of secretion.Supported by grants from the Japanese Educational Ministry. — The technical assistance of Mr. Takeshi Fukunishi is acknowledged with gratitude.     

On the fine structure of the frog's rod outer segments,observed by the freeze-etching technique

Summary The fine structure of the frog's (Rana esculenta) rod outer segments was investigated by two different methods: most of the experiments were made by means of the freeze-etching technique. The replicas were then examined by electron microscopy (40,000 X).By means of a second method, rod outer segments were negatively stained prior to electron microscopy.Inspection of the electron micrographs revealed that the frog's rod outer segments seem to be built up of three groups of elongated structures interpreted as fibrils (Fäden) arranged regularly at approximately equal distances. The diameters of the fibrils are below 100 Å; they depend on the state of light adaptation and on the chemical preparation before freeze-etching. The fibrils partly cross each other. In addition, there were found four groups of approximately equal distances between the fibrils. The order of magnitude of these spacings is from about 50 Å to a few hundred Å.Negatively stained outer segments also reveal fibrils. The results are expressed in a working hypothesis consisting of two parts. It is supposed first that the core of the rod outer segment represents a three dimensional paracrystalline lattice (Raumgitter) of three different types of fibrils (d ₁, d₂, d₄). The distances between the fibrils are interpreted as the lattice constants (a ₁, a₂, a₃, a₄). A unit cell of the lattice would consist of a web (Geflecht) of two different types of fibrils (d ₁, d₂) and four layers of parallel fibrils of the third type (d ₄).It is supposed, secondly, on the basis of a volume-evaluation, that the d₁-fibrils contain rhodopsin, those of type d ₂ another protein (not rhodopsin), and fibrils of type d ₄ lipids.The working hypothesis is supported by experimental findings of other authors (obtained by negative staining and diffraction of light and X-rays).Attempts have been made to relate some electron micrographs of ultrathin sections to those of replicas. (Rosenkranz et al., 1969; Rosenkranz, 1969a.)I wish to thank Prof. Dr. H. Stieve for the interest he took in this work through critical discussions and financial support. I also wish to thank Prof. A. Ruthmann, Ph. D., for introducing me to electron microscopy and for his linguistic aid. That Prof. Dr. K. Mühlethaler, ETH Zürich, and Prof. Dr. F. Schwanitz, KFA Jülich, put their freeze-etching apparatus and electron microscope at my disposal is gratefully acknowledged. The technical assistance of Miss M. Deichmann is also acknowledged.     

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.     

Bacterial adhesion to different termite flagellates: Ultrastructural and functional evidence for distinct molecular attachment modes

Summary The attachment modes of rodlike ectobiotic bacteria to the surface of two different termite flagellates were studied.Devescovina glabra was covered by laterally attached bacteria. Treatment with chemicals that disturb hydrophobic interactions and solubilize proteins removed the ectobionts. Freeze-fracture and freeze-etching electron microscopy revealed rows of intramembrane particles that occurred exclusively along the attachment sites. The adhering Gram-negative bacteria possessed an S-layer (surface layer) composed of globular protein particles. The S-layer could be removed by protein-solubilizing chemicals, e.g., urea, as shown by ultrathin-section electron microscopy. Therefore, it seems plausible that the attachment was mediated by hydrophobic interactions between the flagellate's plasma membrane and the S-layer of the bacteria. The bacteria of the second flagellate,Joenia annectens, adhered by their tips. The attachment was extremely strong. Chemicals disturbing ionic or hydrophobic bindings or solubilizing proteins did not detach the ectobionts. Globular intramembrane protein particles were preferentially found in a ringlike array at the external fracture face of the flagellate's contact sites.Abbreviations DIC differential interference contrast - EGTA ethylene glycol-bis(-aminoethyl ether) N,N,N,N-tetraacetic acid - TEM transmission electron microscope - Tween 20 polyoxyethylenesorbitan     

Envelope ultrastructure of uncultured naturally occurring magnetotactic cocci

Magnetotactic bacteria are microorganisms that respond to magnetic fields. We studied the surface ultrastructure of uncultured magnetotactic cocci collected from a marine environment by transmission electron microscopy using freeze-fracture and freeze-etching. All bacteria revealed a Gram-negative cell wall. Many bacteria possessed extensive capsular material and a S-layer formed by particles arranged with hexagonal symmetry. No indication of a metal precipitation on the surface of these microorganisms was observed. Numerous membrane vesicles were observed on the surface of the bacteria. Flagella were organized in bundles originated in a depression on the surface of the cells. Occasionally, a close association of the flagella with the magnetosomes that remained attached to the replica was observed. Capsules and S-layers are common structures in magnetotactic cocci from natural sediments and may be involved in inhibition of metal precipitation on the cell surface or indirectly influence magnetotaxis.     

Glycolipids are not extracted from phospholipid bilayers by binding to ferritin-lectin conjugates

A radioactively-labelled glycosphingolipid, asialo-G_M1, has been incorporated into phosphatidylcholine multilamellar vesicles. After incubation with ferritin-Ricinus communis agglutinin 60 (RCA 60) conjugate at different temperatures, the vesicles were separated from the conjugate by discontinuous density gradient ultracentrifugation. Measurement of the distribution of the radioactively-labelled asialo-G_M1 in the pelleted conjugate fraction and freeze-etch electron microscopy of the vesicle fraction indicate that the decrease in labelling of vesicles by ferritin-RCA 60 conjugate with increasing temperatures (Tillack, T.W., Wong, M., Allietta, M. and Thompson, T.E. (1982) Biochim. Biophys. Acta 691, 261–273) reflects a decrease in apparent binding affinity rather than an ability of the conjugate to extract glycolipid from the phospholipid bilayer after binding.     

A model for the pattern of deposition of microfibrils in the cell wall of Glaucocystis

Freeze-fracturing of Glaucocystis nostochinearum Itzigsohn cells during cell-wall microfibril deposition indicates that unidirectionally polarized microfibril ends are localized in a zone of synthesis covering about 30% of the sarface area of the plasma membrane. Within this zone there are about 6 microfibril ends/m² cell surface. It is proposed that microfibrils are generated by the passage of their tips over the cell surface and that the pattern of microfibril organization at the poles of the cells, in which microfibrils of alternate layers are interconnected at 3 rotation centres, results directly from the pattern of this translation of microfibril tips. In a model of the deposition pattern it is proposed that the zone of synthesis may split into 3 sub-zones as the poles are approached, each sub-zone being responsible for the generation of one rotation centre. It is demonstrated that the microfibrillar component of the entire wall could be generated by the steady translation of the microfibril tips (at which synthesis is presumed to occur) over the cell surface at a rate of 0.25–0.5 m min^-1. Microcinematography indicates that the protoplast rotates during cell-wall deposition, and it is proposed that this rotation may play a role in the generation of the microfibril deposition pattern.     

A lamellated striated layer in the spore wall of the smut fungus Entorrhiza (Ustilaginales)

Summary The spore wall in the smut fungus Entorrhiza has been investigated, with particular reference to layer 3. The wall is stratified into four layers, numbered 1–4 from the outside to inside of the wall. Layer 3 has a lamellated or striated organization, depending on the type of specimen preparation used for examination. In this study, thin sectioning and freeze-etching methods were used in transmission electron microscopy. Layer 3 is approximately 50 nm thick and is the narrowest layer of the wall. Thin sections viewed at high magnification show a lamellated organization, consisting of alternate electron dense and translucent spaces. Usually between 16–20 lamellae form the layer, with a lamella having a thickness of about 1–2 nm. At high resolution, each electron dense lamella is resolved as a row of closely packed subunits, approximately 1.5 nm in diameter. The electron translucent lamellae probably represent mainly lipoidal material, which is extracted during specimen preparation. In freeze-etch preparations layer 3 is termed the striated layer. Fracturing exposes face views of the layer, which at low magnification has a wrinkled appearance. At high magnification, layer 3 has a structure consisting of an irregular mosaic of striations. The striations in each area of the mosaic are arranged parallel, and regularly spaced 11–13 nm apart. Each area of the mosaic is separated from an adjacent area by a small step; this represents where the plane of fracture changed to a different level within layer 3. Fracturing probably occurs in the lipoidal region of the layer, corresponding to the electron translucent lamellae seen in thin section. At high magnification, the striations are resolved into subunit-like particles, approximately 1–2 nm in diameter. Layer 3 is believed to form an impervious region in the spore wall. Layer 3 in Entorrhiza closely resembles the partition layer reported in spores of other Tilletiaceae. This demonstration of a common wall layer strengthens the relationship between Entorrhiza and the rest of the Tilletiaceae. Entorrhiza is the only smut that forms galls on host roots.     

The fine structure of the bovine Descemet's membrane with special reference to biochemical nature

Summary A freeze-etch replica method combined with biochemical analyses was used to investigate the ultrastructural organization of the bovine Descemet's membrane.The freeze-etch replica observations revealed that the intact Descemet's membranes were composed of stacks of two-dimensionally arranged hexagonal lattices, in which four components were resolved; (1) round densities as nodes, (2) rod-like structures connecting the densities, (3) randomly oriented fine filaments within the lattices, and (4) amorphous materials covering the lattices.When the membranes were treated with sodium dodecyl sulfate (SDS) and mercaptoethanol, only the amorphous materials were solubilized. However, both the amorphous materials and rod-like structures disappeared in SDS-mercaptoethanol-urea-treated membranes. When the membranes were treated with a very low concentration (0.0005%) of collagenase, rod-like structures and round densities remained insoluble. If the concentration was raised to 0.01%, only the round densities persisted.Comparing these data with the amino acid analysis of each fraction, the following conclusions may be drawn: rod-like structures and fine filaments contain collagenous proteins of different solubility, while round densities and amorphous materials are non-collagenous in nature.