Architecture of the cell wall of a green alga,Oocystis apiculata

Summary The cell wall of a green alga,Oocystis apiculata, was visualized by electron microscopy after preparation of samples by rapid-freezing and deep-etching techniques. The extracellular spaces clearly showed a random network of dense fibrils of approximately 6.4 nm in diameter. The cell wall was composed of three distinct layers: an outer layer with a smooth appearance and many protuberances on its outermost surface; a middle layer with criss-crossed cellulose microfibrils of approximately 15–17 nm in diameter; and an inner layer with many pores between anastomosing fibers of 8–10 nm in diameter. Both the outer and the inner layer seemed to be composed of amorphous material. Cross-bridges of approximately 4.2 nm in diameter were visualized between adjacent microfibrils by the same techniques. The cross-bridges were easily distinguished from cellulose microfibrils by differences in their dimensions.     

Structure of Escherichia coli After Freeze-Etching

Survival of Escherichia coli, quick-frozen under conditions similar to those employed for freeze-etching, is close to 100%. For determination of cell shrinkage, the diameters of freeze-etched E. coli cells (average, 0.99 mum) were compared with those of preparations after negative staining and after ultrathin sectioning. Negatively stained cells measured from 0.65 to 1.0 mum in diameter, and ultrathin sections showed average cell diameters of 0.70 mum. Freeze-etched replicas of logarithmically growing, as well as stationary, E. coli B cells revealed a smooth, finely pitted cell surface in contrast to cell surfaces seen with other preparative methods. The frozen cell wall may cleave in two planes, exposing (i) a smooth fracture face within the lipid layer and (ii) in rare instances an ill-defined particulate layer. Most frequently, however, cleavage of the envelope occurred between wall and protoplasmic membrane; large areas of the membrane were then exposed and showed a surface studded with predominantly spherical particles, an appearance which did not significantly change when the cells were fixed in formaldehyde and osmium tetroxide before freeze-etching. The distribution of these particles differed between logarithmically growing cells and stationary cells.     

Fine Structures of Cell Envelopes of Chlamydia Organisms as Revealed by Freeze-Etching and Negative Staining Techniques

The cell walls of Chlamydia psittaci (meningopneumonitis strain) were examined by the freeze-etching and negative staining techniques. It was observed that the cleaved convex surface of the developmental, reticulate body was covered with numerous non-etchable particles 9 to 10 nm in diameter, these particles being rarely seen on the concave surface. Similarly, the convex surface of the mature, elementary body (EB) was covered with many particles but the concavity lacked these particles. After etching, the smooth concave surface of the EB appeared to have a hexagonally arrayed subunit structure, on which the button structure (B structure) was observed. Each B structure had a diameter of 27 nm and several B structures were grouped together in a hexagonal arrangement with a center-to-center spacing of 45 nm. In a limited area of the negatively stained EB cell wall, hexagonally arrayed rosette structures were present, with a center-to-center spacing similar to the B structures seen in the freeze-etched preparation. Each rosette, about 19 to 20 nm in diameter, appeared to be composed of a radial arrangement of nine subunits. The freeze-fractured cell wall-cytoplasmic membrane complexes indicated that the outer surface of the cytoplasmic membrane which appeared as the convex surface was covered with the fine particles, and thus it was likely that frozen EB was cleaved at the gap between the cell wall and ctyoplasmic membrane. On the cleaved inclusion, several groups of fine particles were observed. In each group, the particles were arranged hexagonally with the spacing ranging from 20 to 50 nm.     

Ultrastructure of the Bacteroides nodosus cell envelope layers and surface.

The surface structure and cell envelope layers of various virulent Bacteroides nodosus strains were examined by light microscopy and by electron microscopy by using negative staining, thin-section, and freeze-fracture-etch techniques. Three surface structures were described: pili and a diffuse material, both of which emerged from one or both poles of the bacteria (depending on the stage of growth and division), and large rodlike structures (usually 30 to 40 nm in diameter) associated with a small proportion of the bacterial population. No capsule was detected. The cell envelope consisted of four layers: a plasma membrane, a peptidoglycan layer, an outer membrane, and an outermost additional layer. The additional layer was composed of subunits, generally hexagonally packed with center-to-center spacing of 6 to 7 nm. The outer membrane and plasma membrane freeze-fractured through their hydrophobic regions revealing four fracture faces with features similar to those of other gram-negative bacteria. However, some unusual features were seen on the fracture faces of the outer membrane: large raised ring structure (11 to 12 nm in diameter) on cw 3 at the poles of the bacteria; complementary pits or ring-shaped depressions on cw 2; and small raised ring structures (7 to 8 nm in diameter) all over cw 2.     

The ultrastructure ofAcetivibrio cellulolyticus,a recently isolated cellulolytic anaerobe

The surface and internal structure of air-dried, freeze-dried, or critical-point-dried cells ofAcetivibrio cellulolyticus were determined by negative staining, and by scanning and transmission electron microscopy. The cell wall has five layers, the outermost being the widest. This outermost layer is soft and amorphous, adsorbs cellulose microfibrils, and shows projections of tenuous appearance. Results of staining with heavy ions indicate that the outermost layer carries a net positive charge. The flagellum is a tubular, uniform extension of this outermost layer, about, 20 nm in diameter and approximately 6.4 m long, with no visible internal details or basal body. The inner layers of the wall show no fine structure, other than differences in electron opacity. The cytoplasm is composed of a mixture of densely staining spheres and smaller globules in a background of fine particles. These particles are not completely destroyed by fixation with KMnO₄, which indicates that they are low in ribonucleic acid. There is no evidence for membranes around or outside of any of these bodies.     

Fine Structure of Cryptococcus neoformans Grown In Vitro as Observed by Freeze-Etching

Cryptococcus neoformans grown on culture media was observed by the freeze-etching technique. In the capsule, short fibrils were seen when freezeetched. This organism was unique in the appearance of the cell wall, which showed two strata. The outer one was dense with particles of about 20 nm in diameter, whereas the inner one was sparse in particles. The appearance of the cell membrane of this organism differed distinctly depending on the culture media. When grown on glycerol medium, the cell membrane possessed, as do other yeasts, clear but somewhat longer and curved invaginations. The membrane of cells grown on nonglycerol medium exhibited, however, only a few invaginations of irregular shape. Instead, characteristically of this organism, the cell membrane showed round depressions of 40 to 200 nm in diameter which were the surface view of the paramural bodies. In cross-fractured cells, both types of paramural bodies were found. Some of them contained a single vesicle of about 50 nm in diameter. These seem to play a role in secreting the cytoplasmic vesicles. Data suggesting the existence of multivesicular bodies in the cytoplasm and multivesicular lomasomes were also obtained. Some of the baglike paramural bodies showed multilayered membrane. These are thought to be plasmalemmasomes. This organism was similar to other yeasts reported in other respects.     

Scanning electron microscope study of Saccharomyces cerevisiae spheroplast formation.

A suspension of Saccharomyces cerevisiae NCY366 in buffered 1.2 M sorbitol containing Zymolyase-5000 (a beta-glucanase-containing preparation/showed maximum osmotic sensitivity after 30 min of incubation at 30 degrees C. A scanning electron microscope study of spheroplast formation, using a very high resolution (4-nm) machine, revealed several new morphological features. The surface of the plug in bud scars on intact cells appeared warty. The wall, which assumed a beady appearance as digestion proceded, ultimately sloughed off to reveal the furrowed surface of the plasma membrane. Bud scars were resistant to digestion and. as incubation proceeded, they became surrounded by an outer annulus, which may be the seconary septum. Wall material was completely removed from the majority of cells only after 60 min of digestion. The surface of spheroplasts was studded with particles, about 25 to 30 nm in diameter. Many spheroplasts had a single large indentation, which may be in that part of the plasma membrane originally underlying the birth scar.     

The ultrastructure of cell wall formation and of gamma particles during encystment of Allomyces macrogynus zoospores

Structural changes during cell wall formation by populations of semisynchronously germinating zoospores were studied in the water mold Allomyces macrogynus. Fluorescence microscopy using Calcofluor white ST (which binds to -1,4-linked glycans) demonstrated that Calcofluor-specific material was deposited around most cells between 2–10 min after the induction of encystment (beginning when a wall-less zoospore retracts its flagellum and rounds up). During the first 15 min of encystment there was a progressive increase in fluorescence intensity. Ultrastructural analysis of encysting cells showed that within 2–10 min after the induction of encystment small vesicles 35–70 nm diameter were present near the spore surface, and some were in the process of fusing with the plasma membrane. The fusion of vesicles with the zoospore membrane was concomitant with the appearance of electron-opaque fibrillar material outside the plasma membrane. Vesicles similar to those near the spore surface were found within the gamma () particles of encysting cells. These particles had a crystalline inclusion within the electron-opaque matrix. During the period of initial cyst cell wall formation numerous vesicles appeared to arise at the crystal-matrix interface. Approximately 15–20 min was required for the cell wall to be formed. We suggest that the initial response of the zoospore to induction of encystment is the formation of a cell wall mediated by the fusion of cytoplasmic vesicles with the plasma membrane.Non-Standard Abbreviations GlcNac N-Acetylglucosamine - DS sterile dilute salts solution - PYG peptone-yeast extract-glucose broth     

STRUCTURAL FEATURES OF MESOSOMES (CHONDRIOIDS) OF BACILLUS SUBTILIS AFTER FREEZE-ETCHING

Freeze-etched cells of Bacillus subtilis have been studied with the electron microscope. The outer surface of the plasma membrane, i.e. the side facing the cell wall, is covered with numerous granules and short strands, each measuring approximately 50 A in diameter. These strands are occasionally seen to enter the cell wall. The inner surface of the plasma membrane, i.e. the side facing the cytoplasm, appears to be sparsely dotted with small particles measuring about 50 A. The envelope of mesosomes differs from the plasma membrane. Blunt protrusions arise from its outer surface; the inner surface appears smooth. Stalked particles, as described by other investigators after negative staining with phosphotungstic acid, were not observed on any membrane surface in our material. Preparations were also made of specimens prefixed in osmium tetroxide prior to freeze-etching. Under these conditions the bacterial membranes appeared to be surprisingly well preserved. In contrast to directly frozen, unfixed cells, some osmium tetroxide-fixed preparations showed a differentiation in cytoplasm and nucleoplasm, which made it possible to observe the close association of the mesosome with the latter.     

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.     

Assembly of Cellulose Synthesizing Complexes on the Plasma Membrane of Boodlea coacta

The assembly of cellulose synthesizing complexes (terminal complexes,TCs) on the plasma membrane of Boodlea coacta was investigatedduring the formation of both the matrix-rich layer (MRL) andfibril-rich layers (FRLs) of cell walls. The TCs appeared tobe located mostly within the outer leaflet of the plasma membrane,and were observed as elliptical protrusions consisting of manyparticles of about 9 nm in diameter. Their length varied from100 to 500 nm (average, 220 nm) during MRL formation and from100 to 860 nm (average, 360 nm) during FRL formation. A correlationwas found between the length of TCs and the microfibril widthin both MRL and FRL. On the E-face of the plasma membrane, numerous round protrusions(30–130 nm in diameter), consisting of many particles,8–10 nm in diameter, were also present. Their densitywas greater during FRL formation than during MRL formation.Some of these structures larger than 100 nm were associatedwith microfibril impressions and some appeared to be bound tothe TCs. These protrusions increased in number with Calcofluortreatment but decreased in number when the dye was removed fromthe culture medium. Thus, the TCs may be assembled from massesof particles aggregated on the outer surface of the plasma membrane,and may grow longer by incorporation of these masses. The appearanceof the longer TCs during FRL formation is probably due to thegreater density of these masses. (Received May 1, 1985; Accepted August 16, 1985)     

The fine structure of the pellicle ofEuglena gracilis as revealed by freeze-etching

Summary The ultrastructure of the pellicle ofEuglena gracilis (Klebs) Z strain was studied using the freeze-etching technique and the results were correlated with data obtained from thin sections of fixed material.Examination of freeze-etched pellicles reveals an outer particulate layer and an inner striated layer. The particles of the outer layer measure approximately 150 Å in diameter. The striations of the inner layer are about 50 Å wide and are separated from each other by about 35 Å. A broad repeating pattern is also visible with a periodicity of about 450 Å. When deep etching is employed, a smooth outer layer is seen covering the particulate layer. This is probably the outer surface of the plasma membrane. Mucilage is present on the outer surface of the cell and is seen as a substructure of threads superposed on the smooth layer of plasma membrane.Thin sectioning also shows a striated layer interior to the plasma membrane. This appears to be identical to the striated layer seen after freeze-etching.     

Topography and functional information of plasma membrane

By using atomic force microscope (AFM), the topography and function of the plasmalemma surface of the isolated protoplasts from winter wheat mesophyll cells were observed, and compared with dead protoplasts induced by dehydrating stress. The observational results revealed that the plasma membrane of living protoplasts was in a state of polarization. Lipid layers of different cells and membrane areas exhibited distinct active states. The surfaces of plasma membranes were unequal, and were characterized of regionalisation. In addition, lattice structures were visualized in some regions of the membrane surface. These typical structures were assumed to be lipid molecular complexes, which were measured to be 15.8±0.09 nm in diameter and 1.9±0.3 nm in height. Both two-dimensional and three-dimensional imaging showed that the plasmalemma surfaces of winter wheat protoplasts were covered with numerous protruding particles. In order to determine the chemical nature of the protruding particles, living protoplasts were treated by proteolytic enzyme. Under the effect of enzyme, large particles became relatively looser, resulting that their width was increased and their height decreased. The results demonstrated that these particles were likely to be of protein nature. These protein particles at plasmalemma surface were different in size and unequal in distribution. The diameter of large protein particles ranged from 200 to 440 nm, with a central micropore, and the apparent height of them was found to vary from 12 to 40 nm. The diameter of mid-sized protein particles was between 40―60 nm, and a range of 1.8―5 nm was given for the apparent height of them. As for small protein particles, obtained values were 12―40 nm for their diameter and 0.7―2.2 nm for height. Some invaginated pits were also observed at the plasma membrane. They were formed by the endocytosis of protoplast. Distribution density of them at plasmalemma was about 16 pits per 15 μm2. According to their size, we classified the invaginated pits into two types―larger pits measuring 139 nm in diameter and 7.2 nm in depth, and smaller pits measuring 96 nm in diameter and 2.3 nm in depth. On dehydration-induced dead pro-toplasts, the degree of polarization of plasma membranes decreased. Lipid molecular layers appeared relatively smooth, and the quantity of integral proteins reduced a lot. Invaginated pits were still de-tectable at the membrane surface, but due to dehydration-induced protoplast contraction, the orifice diameter of pits reduced, and their depth increased. Larger pits averagely measuring 47.4 nm in di-ameter and 31.9 nm in depth, and smaller pits measuring 26.5 nm in diameter and 43 nm in depth at average. The measured thickness of plasma membranes of mesophyll cells from winter wheat examined by AFM was 6.6―9.8 nm, thicker in regions covered with proteins.     

Fine Structure of the Oocyst Wall of Eimeria nieschulzi

SYNOPSIS. Oocysts of Eimeria nieschulzi from the laboratory rat, Rattus, norvegicus , were studied by scanning and transmission electron microscopy. Oocysts had a rough outer wall with apparent random depressions. The oocyst wall is composed of 2 layers: an osmiophilic outer layer consisting of a rough external and smooth internal surface, and a relatively thick, electron-lucent inner layer. The outer layer is composed of a dense, coarsely granular matrix. The inner layer consists of homogeneous fine granular material interspersed with coarse osmiophilic granules and contains one closely applied membrane on the outermost surface. Several raised lenticular areas are seen on the coarse outer surface of the inner layer. These layers are 102 (75–128) and 176 (135–204) nm thick, respectively.
The sporocyst wall is thin, consisting of 3 to 4 unit membranes, and measures 27 (18–34) nm thick.     

Outer membrane of Salmonella typhimurium: chemical analysis and freeze-fracture studies with lipopolysaccharide mutants.

The outer membrane layer of the cell wall was isolated from wild-type Salmonella typhimurium LT2 as well as from its mutants producing lipopolysaccharides with shorter saccharide chains. Chemical analysis of these preparations indicated the following. (i) The number of lipopolysaccharide molecules per unit area was constant, regardless of the length of the saccharide side chain in lipopolysaccharide. (ii) In contrast, in "deep rough" (Rd or Re) mutants producing the lipopolysaccharides with very short saccharide chains, the amount of outer membrane protein per unit surface area decreased to about 60% of the value in the wild type. (iii) In the wild type, the amount of phospholipids is slightly less than what is needed to cover one side of the membrane as a monolayer. In comparison with the wild type, the outer membrane of Rd and Re mutants contains about 70% more phospholipids, which therefore must be distributed in both the outer and inner leaflets of the membrane. Freeze-fracture studies showed that the outer membrane of Re mutants were easily fractured, but fracture became increasingly difficult in strains producing lipopolysaccharides with longer side chains. The convex fracture face was always nearly smooth, but the concave fracture face or the outer half of the membrane was densely covered with particles 8 to 10 nm in diameter. The density of particles was decreased in Re mutants to the same extent as the reduction in proteins, suggesting the largely proteinaceous nature of particles. A model for the supramolecular structure of the outer membrane is presented on the basis of these and other results.     

Structure of Micrococcus denitrificans and M. halodenitrificans Revealed by Freeze-etching

S ummary . After freeze-etching, cells of Micrococcus denitrificans and M. halodenitrificans revealed structures similar to those observed in ultrathin sections. Both organisms had a similar cell wall structure. The cell wall was double layered, the smooth surface of which had a delicate granular structure. The cytoplasmic membrane was in 2 parts, both covered with spherical particles 8–12 nm diam. The cytoplasmic membrane possessed rod-shaped invaginations (100–300 × 30–50 nm). The cytoplasm of both species contained inclusions of poly-β-hydroxybutyric acid.     

Electron Microscopic Study of Membranes and Walls of Bacteria and Changes Occurring During Growth Initiation

Thin sections of stationary-phase Streptococcus lactis cells showed that the wall and membrane are 20 and 7 nm thick, respectively. Whole cells were examined by negative staining with ammonium molybdate and by shadowing. On air-drying of whole cells, the membrane pulled away from the wall revealing adhesions between these organelles. Adhesions could not be seen after subculture of the stationary-phase cells into complex media or into solutions containing glucose, KCl, and CaCl(2) in tris(hydroxymethyl)aminomethane buffer. The adhesions were also observed in stationary-phase cells of other gram-positive bacteria. Fractured freeze-etched cells of S. lactis had a smooth outside surface, but the inside of the wall (or outside of the membrane) had a regular structure, repeating at 10 nm, which could correspond to the adhesions observed in the negatively stained air-dried cells. Freeze-etching also revealed holes in the outside wall which had the shape of inverted truncated cones. The outside diameter of the cone was 60 nm, and the diameter on the inside surface of the wall was 20 nm. The membrane had upstanding plugs, 20 nm in diameter, which could fill the holes in the wall.     

Pellicle of Paramecium caudatum as Revealed by Freeze Etching

SYNOPSIS. Freeze etching study of Paramecium caudatum surface reveals a regular pattern formed by depressions equipped with a single or paired cilia. This picture is consistent with the generally accepted concept of Paramecium cortex based on conventional methods of study. The surface of the ciliate is covered with small globular particles ∼14 nm in diameter, which have been found also on the plasma membrane of other cells. In the areas where the tips of trichocysts are attached to the pellicle, the globular particles are arranged into circles 0.4 μm in diameter. The whole surface of Paramecium is covered by a smooth thin layer which, always chipped off during fracturing, is detectable only after etching.     

Quantitative immunocytochemical localization of Na+,K+-ATPase alpha-subunit in the lateral wall of rat cochlear duct

Ultrastructural localization of the alpha-subunit of Na+,K+-ATPase on the lateral wall of rat cochlear duct was investigated quantitatively by the protein A-gold method, using affinity-purified antibody against the alpha-subunit of rat kidney Na+,K+-ATPase. In the stria vascularis, gold particles were sparse over the endolymphatic luminal surface of the marginal cells but were numerous over the basolateral membrane. The labeling density of the basolateral membrane was almost equal to that of the same domain of the distal tubule cells of kidney. The intermediate cells were studded with a large number of gold particles on the plasma membrane domain facing the basolateral domain of the marginal cells. On the luminal surfaces of the other epithelial cells, including those of Reissner's membrane, no significant amount of gold particles was found. Many gold particles were localized on all the plasma membranes of the spiral prominence stromal cells and on the intracellular membrane domain of the external sulcus cells.     

An examination of the developing cotton fiber: Wall and plasmalemma

Summary The ultrastructure of developing cotton fibers has been examined using novel modifications of the techniques of surface replication, freeze-etching and thin-sectioning. The fiber surface was found to be coated with a lamellar cuticle, which is stretched and thinned as the fiber elongates. It is marked by bars which run parallel with the fiber long axis. Beneath the cuticle, the outermost microfibrils of the primary wall lie parallel with the fiber axis, while those adjacent to the plasma membrane are transverse. Primary wall microfibrils are present in bundles, disposed in left-handed and right-handed helices, which correspond with the fibrils observed optically. Microfibrils within bundles form in-phase waves, with wavelengths and amplitudes in the ranges 0.3–7 m and 0.01–0.1 m in primary and secondary walls respectively. As elongation proceeds bundles become displaced towards the cell axis. Microfibrils of the secondary wall, disposed around the cell as fast helices, are similarly bundled and wavy (though with a reduced amplitude). In surface-replicas, large (20–30 nm) granules are present on the cytoplasmic face of the wall which probably correspond with 20–40 nm low prominences visible on freeze-etch EF plasma membrane fracture faces. It is proposed that these may be microfibril-synthesizing centers. Plasma membranes fracture such that the membrane-associated-particles segregate 6040 between P and E fracture moieties, but the prominence and total number of these particles is reduced at the stage of secondary wall formation as compared with primary wall formation. Beneath the plasmalemma the axes of microtubules parallel secondary wall microfibril orientation. Cross-bridges, which stain heavily after glutaraldehyde/tannic acid fixation, link microtubules to plasma membrane. The use of butyl benzene to cement fragments of cotton fibers, employed in this work, may prove useful in other freeze-etch studies of long fibers which are readily ruptured during preparation.