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1.
It is known that the negatively stained preparations of inner mitochondrial membrane display characteristic ∼9 nmF
1 (ATPase) knobs projecting from the matrix surface. Freeze-etch studies have reported the absence of such knobs from the “etched”
surface of the inner mitochondrial membranes. We have demonstrated their presence on the surface of SMP (submitochondrial
particles) prepared by freeze-drying for transmission electron microscopy. This identification has been substantiated by comparison
with the freeze-dried TU particles (trypsin-urea treated SMP) that are devoid ofF
1 (ATPase). It has been suggested that a layer of water molecules is strongly adsorbed to the surface of SMP and does not sublime
during normal freeze-“etching.” 相似文献
2.
The detailed knowledge of the molecular process of mechanotransduction is still an unsolved question. The investigation of the intramembranous structure of the cutaneous mechanoreceptors may play an important role in elucidating this problem. In this relation, Herbst sensory corpuscles in ducks were studied for the first time using the freeze-etching and thin sectioning techniques. Herbst corpuscles have the basic structural components valid for most of the encapsulated mechanoreceptors in mammals: a capsule made of perineural cells, a lamellar complex of modified Schwann cells, surrounding the non-myelinated part of the receptor nerve fiber and its ending. Freeze-etching replicas reveal that the plasmalemmae of the capsule cells, modified Schwann cells and axolemmae of parts of the nerve fiber differ in both density and pattern of distribution of intramembranous particles (IMPs) as well as IMP size. On all the plasmalemmae the IMP density is higher on the P-face (2000–3300?µm?2) than the respective E-face (800–1500?µm?2). The axolemma of the ending of the receptor nerve fiber expresses higher density of IMPs than its shaft. The mean IMP size for all the plasmalemmae varies between 5.5 and 7.5?nm. Many tight junctions occur between the capsule cells. These results indicate that the non-myelinated axolemma as well as the plasmalemmae of other components of Herbst corpuscles are specialized in terms of content and distribution of IMPs. The IMPs may represent various kinds of mechanosensitive channel proteins or related membrane-bound proteins participating in the process of mechanotransduction. 相似文献
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4.
Marlene Benchimol Bechara Kachar Wanderley De Souza 《Biology of the cell / under the auspices of the European Cell Biology Organization》1993,77(3):289-295
Summary— The quick-freezing and freeze-etching technique was used to analyse the cytoskeleton of Tritrichomonas foetus, a pathogenic protozoan of the urogenital tract of cattle. The cytoplasm presented a network of filamentous structures interacting with each other, with the surface of the hydrogenosomes and the nuclear membrane. Two nm wide filamentous structures were found in the luminal space of the Golgi complex, connecting the two faces of each cisterna. The microtubules of the pelta-axostyle system were connected by bridges 30–40 nm long and 10 nm wide, regularly spaced with an interval of 25 nm. The costa is a structure formed by a complex array of filaments and globous structures. It seems to be connected to the recurrent flagellum through a complex network formed by 15 and 10 nm wide filaments which emerge from the peripheral region of the costa and penetrate into the surface projections of the protozoan body to which the recurrent flagellum is attached. Other filaments were seen connecting the surface of these projections with the surface of the flagellum. 相似文献
5.
An ultrastructural study was made of the spore envelope during development in the microsporidan, Thelohania bracteata. The frozen-etched outer (convex) face of the relatively thin spore coat in the earliest immature stage of development has a granular structure in regular array. The inner (concave) face bears particles as well as depressions arranged in a net-like pattern. The mature spore coat has a substructure of numerous microfibers, ~8 nm in diameter, arranged in a matrix and forming thin layers which run parallel to the spore surface. The mature spore coat possesses both outer and inner limiting layers. The outer (convex) face of the outer limiting layer is granular. The convex face of inner limiting layer bears many particles as well as many long, narrow depressions. The concave face of the inner limiting layer carries many stud-like projections, ~40 nm long and 30 nm high, which are complementary to the depressions observed on the convex face. In addition, the concave face has subunits ~15 nm in diameter, apparently arranged in a hexagonal pattern with a center to center distance of ~18 nm. The change in size of these projections, depressions, and subunits presumably is related to spore maturation. 相似文献
6.
ALEXANDER J. SULZER PHYLLIS L. STROBEL E. LOUISE SPRINGER IVAN L. ROTH CAREY S. CALLAWAY 《The Journal of eukaryotic microbiology》1974,21(5):710-714
SYNOPSIS. Freeze-etch preparations of Toxoplasma gondii reveal details of structure and organelles in 3-dimensional relationships. The subpellicular microtubules and their relationship to the polar ring, the tripartite pellicle, the pellicle constituents, and the spatial relationship of the rhoptries to the conoid and conoid canal are clearly demarcated. 相似文献
7.
Cell wall structure and biogenesis in the unicellular green alga, Oocystis apiculata, is described. The wall consists of an outer amourphous primary layer and an inner secondary layer of highly organized cellulosic microfibrils. The primary wall is deposited immediately after cytokinesis. Golgi-derived products contribute to this layer. Cortical microtubules underlie the plasma membrane immediately before and during primary wall formation. They function in maintaining the elliptical cell shape. Following primary wall synthesis, Golgi-derived materials accumulate on the cell surface to form the periplasmic layer. This layer functions in the deposition of coating and cross-linking substances which associate with cellulosic microfibrils of the incipient secondary wall. Secondary wall microfibrils are assembled in association with the plasma membrane. Freeze-etch preparations of untreated, living cells reveal linear terminal complexes in association with growing cellulosic microfibrils. These complexes are embedded in the EF fracture face of the plasma membrane. The newly synthesized microfibril lies in a groove of the outer leaflet of the plasma membrane. The groove is decorated on the EF fracture face by perpendicular structures termed “ridges.” The ridges interlink with definitive rows of particles associated with the PF fracture face of the inner leaflet of the plasma membrane. These particles are termed “granule bands,” and they function in the orientation of the newly synthesized microfibrils. Microfibril development in relation to a coordinated multienzyme complex is discussed. The process of cell wall biogenesis in Oocystis is compared to that in higher plants. 相似文献
8.
Jelly coats surrounding the eggs of the South African clawed toad, Xenopus laevis, consist of three transparent, gelatinous layers: the innermost layer (J1), the middle layer (J2), and the outer layer (J3). The distribution of N-acetylglucosamine within these jelly coats, as probed with FITC-conjugated wheat germ agglutinin (WGA-FITC), and the matrix ultrastructure of each layer, as visualized in platinum replicas produced by the quick-freeze, deep-etch, and rotary-shadowing technique, suggests that each layer has a unique fiber and glycoprotein composition. J1 extends nearly 200 μm from the egg surface and exhibits no WGA-FITC staining. Stereo images of platinum replicas indicates that J1 consists of a tightly knit network of 5–10 nm fibers decorated with 10–20 nm particulate components. In contrast, J2 is a relatively thin layer, extending only 25–40 μm from the outer aspect of J1. When visualized by confocal microscopy, J2 displays a multilayered WGA-FITC staining pattern. The ultrastructure of J2 consists of sheets of fine fibers that run parallel to one another and that can be identified by their ability to bind WGA-colloidal gold. The fibers of each sheet run at an oblique angle to fibers in neighboring layers. J3 extends 100 μm or more from J2. The WGA-FITC staining pattern shows high intensity in its outer region and less intensity in regions closer to J2. Like J1, the J3 ultrastructure consists of a network of 5–10 nm fibers, decorated with 10–20 nm particulate components. The results of these studies add to a growing body of information that suggests the jelly coats surrounding the eggs of many animals consist of a fibrous glycoprotein superstructure that acts as a scaffold to which globular glycoproteins are bound. © 1996 Wiley-Liss, Inc. 相似文献
9.
Membrane vesicles in magnetotactic bacteria 总被引:4,自引:0,他引:4
Magnetotactic bacteria are microorganisms that respond to magnetic fields. We have studied the surface ultrastructure of Magnetospirillum magnetotacticum and uncultured magnetotactic bacteria from a marine environment using transmission electron microscopy and freeze-etching. Numerous membrane vesicles were observed on the surface of Magnetospirillum magnetotacticum bacteria. All uncultured magnetotactic bacteria presented membrane vesicles on their surface in addition to an extensive capsular material and an S-layer formed by particles arranged in a hexagonal symmetry. We did not observe any indication of electron-dense precipitation on the surface of these microorganisms. Our results indicate that membrane vesicles are a common characteristic of magneto-tactic bacteria in natural sediments. 相似文献
10.