Determination of the spiral conformation of Aquaspirillum spp. by scanning electron microscopy of elongated cells induced by cephalexin treatment

The effect of the beta-lactam antibiotic cephalexin on the spiral conformation of cells of Aquaspirillum spp. was examined by scanning electron microscopy. A. itersonii and A. peregrinum, which are known to have a left-handed spiral shape, elongated and still showed left-handed spirals in medium containing cephalexin. The spiral conformation of the elongated cells is therefore considered to represent the natural condition. The spiral conformations of A. metamorphum and A. psychrophilum grown in ordinary cultures were difficult to determine because they have short cells without a complete spiral. After cephalexin treatment, the cells of these species elongated and displayed spiral forms, right-handed in A. metamorphum and left-handed in A. psychrophilum. This elongation method may be useful for checking and determination of the spiral handedness of short spiral or curved bacteria such as vibrios.     

Helix handedness of Leptospira interrogans as determined by scanning electron microscopy.

Representative serovars and strains of the seven genetic groups of Leptospira interrogans, and two previously studied serovars, were all found to form exclusively right-handed helices as determined by scanning electron microscopy. No change in handedness occurred in cells grown in a minimal medium (Tween-80 albumin) compared to cells grown in a rich medium (rabbit serum). The right-handedness of the organisms was related to the evolution, cell wall structure, and the mechanism of motility of L. interrogans.     

Structure of trichomonads as revealed by scanning electron microscopy.

A scanning electron microscope (SEM) study of Hypotrichomonas acosta (Moskowitz), Trichomonas vaginalis Donné, Pentatrichomonas hominis (Davaine), and Tritrichomonas foetus (Riedmüller) provided new information about the structure of the periflagellar canal; emergence of the flagella from the cell body; structure of the undulating membrane; and position, shape, and size of the pelta. Of special interest were the spatial relationships of the attached part of the recurrent flagellum and the accessory filament in Hypotrichomonas and in the members of Trichomonadinae, i.e. Trichomonas and Pentatrichomonas.     

H-pilus assembly kinetics determined by electron microscopy.

The kinetics of pilus outgrowth were examined for Escherichia coli containing pDT1942, a TnlacZ insertion derivative of the IncHI1 plasmid R27, which was derepressed for transfer. IncHI1 plasmids are thermosensitive for transfer. The pili specified by pDT1942 were examined by transmission electron microscopy after the pilus had been labeled with the H-pilus-specific bacteriophage Hgal, which had been inactivated with RNase A. H pili were extended by extrusion from the cell surface and not by the addition of pilin subunits to the pilus tip. After pili were removed by vortexing, the outgrowth of full-length pili (2 microns long) required 20 min. H pili expressed at the transfer optimal temperature (27 degrees C) remained stable after incubation at the transfer inhibitory temperature (37 degrees C), but the formation of mating aggregates was inhibited at 37 degrees C. Within 1 min of exposure of the host cell to a heat stimulus of 50 degrees C, pili vanished. Pili were observed in straight and flexible forms with a field emission scanning electron microscope, which may indicate a dynamic role for the pilus in conjugation.     

Transmission electron microscopy of tissue prepared for scanning electron microscopy by ethanol-cryofracturing.

Tissue processed for scanning electron microscopy by ethanol-cryofracturing combined with critical point drying was embedded and sectioned for transmission electron microscopy. Study of specimens cut in a plane passing through the fracture edge indicated that preservation of cellular fine structure of fractured cells was excellent. Even at the most peripheral edge of the fracture there was no evidence that movement of cytoplasmic components occurred to distort the original structural organization of fractured cells. Lack of cytoplasmic detail in ethanol-cryofractographs has been due more to the nature of the fracturing of the tissue and to the obscuring effects of the metal coating than to structural deformation at the fracture edge or to limitations in resolving power of the scanning electron microscope used.     

Architecture of chitin gel as examined by scanning electron microscopy

An architecture of the solid phase of chitin gel was examined by scanning electron microscopy. The ultrastructure of the xerogel was microporous with parallel channels surrounded with membranous walls. The pore shapes at cross section were polyhedral with three walls at the junctions. The pore was 30–50 μm in diameter and 80–300 μm in length, and the thickness of the walls was less than 1.5 μm. The gel is considered to be a polyphasic gel, consisting of small droplets of water held up in these pores.     

Membrane contents of distinct subpopulations of coated vesicles determined by scanning transmission electron microscopy

In order to investigate the heterogeneity of clathrin-coated vesicles purified from rat liver, and to quantitate rigorously their membrane contents, we have analyzed scanning transmission electron micrographs of unstained coated vesicles before and after extraction with the non-ionic detergent Triton X-100, as well as of vesicles whose coats had been removed by dialysis against 10 mM or 100 mM Tris (pH 8.2). Their respective distributions of particle masses were thus determined and compared, in light of complementary biochemical quantitations of lipid and protein. Smaller coated particles, 25-45 MDa in mass and 60-80 nm in diameter, lose no mass when extracted with Triton, and disappear when their coats are dissociated. We conclude that they do not contain membrane vesicles, although they have dense, presumably proteinaceous, cores. They may represent particles generated during tissue homogenization or, possibly, a storage form of clathrin. The remaining 70% contain bona fide vesicles: these particles are 75-150 nm in diameter, and their average mass is about 80 MDa, of which 48 MDa is contributed by coat proteins, 10-12 MDa by phospholipid and cholesterol, and 20-22 MDa by vesicle-associated proteins. Their vesicles are of two types: smaller, denser, vesicles that contain substantial amounts of internalized material, and larger, less dense, vesicles that do not. The distinction between them may, in view of other findings, reflect a difference between coated vesicles derived respectively from the Golgi and the plasma membrane.     

A comparison of the size of photoreceptor cells from the retina of the domestic pig as determined by light and scanning electron microscopy

While gathering data on the visual pigments of numerous species, many light micrographs have been taken of the photoreceptor cells containing the visual pigment after spectral recordings have been made from these cells. These micrographs are used to view the cells and obtain measurements of their size. Usually the morphology of the photoreceptor cells is retained adequately so that such measurements can be taken. Occasionally it is necessary to partially fix the retinal tissue which aids in the maintenance of photoreceptor morphology while allowing visual pigment spectral recordings to be made. We have found that primate retinal tissue, as well as some other mammalian tissue, disintegrates rapidly. Although partial fixation allows spectral recordings to be made before the micrographs are taken, the treatment does not always adequately preserve cell morphology for quality micrographs to be obtained. In these cases, visual pigment recordings are made from pieces of unfixed and partially fixed retinal tissue; an additional piece of the same retinal material is well-fixed, embedded and thick-sectioned for light microscopy.Preparing retinal material for sectioning is lengthy and time consuming so an alternative tissue preparation technique was sought. Material can be processed for the scanning electron microscope (SEM) more rapidly than for sectioning, however severe tissue shrinkage occurs during this process. It was found that although shrinkage does occur in the retinal tissue prepared for SEM, the relative proportions of the photoreceptor cells are maintained extremely well. Using the critical point drying method (CPD) pig retinal tissue was prepared for SEM. Scanning electron micrographs of the pig photoreceptors were taken for cell measurement. Since these micrographs could be made at higher magnification than is available by light microscopy, a more detailed view of the pig photoreceptor cells was obtained. Cell measurements made from the light and the scanning electron micrographs indicate that an approximate shrinkage of 50% occurs in the SEM prepared material.     

Aspects of the three-dimensional intracellular organization of mesocarp cells as revealed by scanning electron microscopy

Summary The osmium-ligand binding technique and scanning electron microscopy have been applied to the study of the three-dimensional organization of mesocarp cells of a mature avocado fruit. Using this approach the mitochondria of the cells appear as elongated, branching structures and the endoplasmic reticulum consists of a complex of tubular strands, vesiculated strands and lamellar sheets. Associations of the endoplasmic reticulum with other organelles are also apparent. It is suggested that this approach provides a valuable means to assess the structural transitions in cell organization that occur during development or with functional changes.     

Field emission scanning electron microscopy of plant cells

Summary Two basic specimen preparation protocols that allow field emission scanning electron microscope imaging of intracellular structures in a wide range of plants are described. Both protocols depend on freeze fracturing to reveal areas of interest and selective removal of cytosol. Removal of cytosol was achieved either by macerating fixed tissues in a dilute solution of osmium tetroxide after freeze fracturing or by permeabilizing the membranes in saponin before fixation and subsequent freeze fracturing. Images of a variety of intracellular structures including all the main organelles as well as cytoskeletal components are presented. The permeabilization protocol can be combined with immunogold labelling to identify specific components such as microtubules. High-resolution three-dimensional imaging was combined with immunogold labelling of microtubules and actin cables in cell-free systems. This approach should be especially valuable for the study of dynamic cellular processes (such as cytoplasmic streaming) in live cells when used in conjunction with modern fluorescence microscopical techniques.Abbreviations DMSO dimethylsulfoxide - FESEM field emission scanning electron microscope (-scopy) - MTSB microtubule-stabilizing buffer - PBS phosphate-buffered saline - SEM scanning electron microscope (-scopy) - TEM transmission electron microscope (-scopy)     

Structure of the vacuolar ATPase from Neurospora crassa as determined by electron microscopy.

We have examined the structure of the vacuolar ATPase of Neurospora crassa using negatively stained preparations of vacuolar membranes and of detergent-solubilized and gradient-purified ATPase complexes. We also examined the peripheral sector (V1) of the enzyme after it had been removed and purified. Using different stains, vacuolar membranes displayed ball-and-stalk structures similar to those of the intact mitochondrial ATPase. However, the vacuolar ATPase was clearly different from the mitochondrial ATPase in both size and structural features. The vacuolar enzyme had a much larger head domain with a distinct cleft down the middle of the complex. This domain was held above the membrane by a prominent stalk. Most intriguing was the presence of basal components. These structures appeared to project from the vacuolar membrane near the base of the stalks. Detergent-solubilized, gradient-purified ATPases displayed the same head, stalk, and basal features as those found with the intact enzyme on vacuolar membranes. The mitochondrial ATPase was significantly smaller, and no clefted head domains or basal components were observed. When V1 and F1 particles were directly compared, a significant difference in size and shape between these two soluble ATPase sectors was apparent. V1 retained all of the features seen in the globular head of the intact complex: V-shaped, triangular, and square forms around a stain-filled core.     

Organization of designed nanofibrils assembled from alpha-helical peptides as determined by electron microscopy.

Self-assembling peptides present attractive platforms for engineering materials with controlled nanostructures. Recently, an alpha-helical fibril forming peptide (alphaFFP) was designed that self-assembles into nanofibrils at acid pH. Circular dichroism spectroscopy, electron-microscopy and x-ray fibre diffraction data showed that the most likely structure of alphaFFP fibrils is a five-stranded coiled coil rope. In the present study, scanning transmission electron microscopy (STEM) was used to improve our understanding of the alphaFFP fibril structure. The measurements of fibril mass per length suggest that there are ten alpha-helices in transverse sections of the fibrils. Based on the known data, it is proposed that a predominant fibrillar structure of alphaFFP is a dimer of alpha-helical five stranded protofilaments wrapped around a common axis. It is shown that these structures have an axial dimension of 58 +/- 16 nm and a width of 4 +/- 1 nm. A small number of thin fibrils is also observed in the negative stained preparation and STEM images. The thin fibrils may correspond to the single protofilament.     

Examination of immobilized fungal cells by phase-contrast and scanning electron microscopy

Conidia of Penicillium urticae were immobilized in kappa-carrageenan beads and then shaken, in a growth-supporting medium to yield an in situ grown population of mycelia. The physical stability of these beads and the degree of mycelial growth inside the beads were significantly affected by the concentrations of kappa-carrageenan and locust bean gum (LBG) in the bead matrix and by the porous or nonporous nature of the interior. Thus 16-h-old porous and nonporous beads, prepared from 1.25% kappa-carrageenan, 0.5% LBG, and conidia, possessed a very dense mycelial mass at the surface. Only the porous beads possessed a moderately dense mycelial mass at the centre. The conidia at the centre of nonporous beads either failed to germinate or formed very small germ tubes. When washed, 36-h-old porous beads were repeatedly (i.e., 48 h) transferred into nitrogen-free medium, the density of mycelia at the centre increased to equal that at the surface after three transfers or 8 days. Mycelia at the surface exhibited signs of physical damage, while those in the centre did not. The addition of 100 micrograms/mL of cycloheximide to these replacement cultures was reflected by the distortion of interior mycelia.     

Laser microdissection of fungal septa as visualised by scanning electron microscopy

Laser microdissection has been proven a successful technique to isolate single cells or groups of cells from animal and plant tissue. Here, we demonstrate that laser microdissection is suitable to isolate subcellular parts of fungal hyphae. Dolipore septa of Rhizoctonia solani containing septal pore caps were cut by laser microdissection from sections of mycelium and collected by laser pressure catapulting. Subsequently, microdissected septa were visualised using a wheat germ agglutinin labelling of cell walls, septa and septal pore caps and scanning electron microscopy. The use of laser microdissection on fungal cells opens new ways to study subcellular fungal structures and the biochemical composition of hyphal cells.