A Scanning Electron Microscopic Evaluation of Section and Film Mounting for Transmission Electron Microscopy

Mounting of support films and sections for transmission electron microscopy has been examined with the scanning electron microscope. Experiments have been designed to test the adherence of support films to polished and matte surfaces of specimen grids. It is the conclusion of the authors that sections and films should be mounted on the dull or matte surface of Athene-type specimen grids.     

SOME EFFECTS OF THE MICROTOME KNIFE AND ELECTRON BEAM ON METHACRYLATE-EMBEDDED THIN SECTIONS

A technique for the examination of specimens at low electron beam intensity has been presented. Sections micrographed with this technique showed numerous knife scratches and frequently contained bands running parallel to the knife edge. Banding with an average spacing of 0.2 µ appeared to result from periodic distortion produced by impact of the knife. At the beam intensities customarily employed, differential sublimation and probably flow of the methacrylate resulted in obliteration of the bands and all but the deepest knife scratches. In addition, changes in the size, shape, and orientation of certain structures were noted. Artifacts resulting from incineration or sublimation of tissue components fixed in formalin were illustrated, and the suggestion was made that such instability to the electron beam accounted in part for the differences observed in osmium- and formalin-fixed tissues. The deformation revealed in serial sections was discussed, and it was pointed out that shortening in the axis perpendicular to the knife edge was associated with elongation in the axis parallel to the cutting edge, the elongation usually occurring locally without change in the width of the section. It was noted that the material causing contamination of the surface of sections during examination exhibited no structure but caused progressive loss of contrast.     

Interpretation of electron micrographs of single and serial sections

A method of securing serial sections for electron microscopy is described. Serial sections present certain anomalies of interpretation of a nature such that a complete and detailed three-dimensional reconstruction of the sectioned tissue cannot be made. These anomalies are discussed, as well as those which have been encountered in the interpretation of single sections. Observations of the following kinds have been made in an attempt to elucidate the interpretation of single and serial sections: differing methods of mounting adjacent sections, observation of the same section by high-angle stereoscopy, and examination of sections which have been shadowed prior to and subsequent to electron microscopy. It is found that the appearance of sections is independent of the choice of side to be placed against the formvar films. Stereoscopy shows that the appearance of fine structures is strongly dependent upon the direction of the penetrating electron beam with respect to the plane of the structures. Stereoscopy, combined with shadowing, shows quantitatively that extensive sublimation of polymer occurs upon normal exposure in the electron microscope. Observation of sections shadowed prior to electron microscopy indicates that varying amounts of material are removed between sections by the action of microtomy; i.e., it is probable that the sum of the thicknesses of several serial sections is considerably less than the total thickness of material removed from the block. It is believed that this effect, combined with the effect of sublimation, aids in explaining the failure of adjacent sections to exhibit continuity in their detailed structures.     

INTERPRETATIONS OF ELECTRON MICROGRAPHS OF SINGLE AND SERIAL SECTIONS

A method of securing serial sections for electron microscopy is described. Serial sections present certain anomalies of interpretation of a nature such that a complete and detailed three-dimensional reconstruction of the sectioned tissue cannot be made. These anomalies are discussed, as well as those which have been encountered in the interpretation of single sections. Observations of the following kinds have been made in an attempt to elucidate the interpretation of single and serial sections: differing methods of mounting adjacent sections, observation of the same section by high-angle stereoscopy, and examination of sections which have been shadowed prior to and subsequent to electron microscopy. It is found that the appearance of sections is independent of the choice of side to be placed against the formvar films. Stereoscopy shows that the appearance of fine structures is strongly dependent upon the direction of the penetrating electron beam with respect to the plane of the structures. Stereoscopy, combined with shadowing, shows quantitatively that extensive sublimation of polymer occurs upon normal exposure in the electron microscope. Observation of sections shadowed prior to electron microscopy indicates that varying amounts of material are removed between sections by the action of microtomy; i.e., it is probable that the sum of the thicknesses of several serial sections is considerably less than the total thickness of material removed from the block. It is believed that this effect, combined with the effect of sublimation, aids in explaining the failure of adjacent sections to exhibit continuity in their detailed structures.     

AUTORADIOGRAPHIC DETERMINATION OF S35 IN TISSUES AFTER INJECTION OF METHIONINE-S35 AND SODIUM SULFATE-S35

The loss of "bound" S³⁵ that occurs during various mounting procedures used in autoradiography was studied in healing surface wounds of rats treated with either methionine-S³⁵ or Na₂S³⁵O₄. Valid autoradiography of bound S³⁵ in this tissue is not possible until 48 hours after radiosulfate and 24 hours after radiomethionine injection, when the S³⁵ is almost entirely bound in large protein and polysaccharide molecules. Autoradiograms of S³⁵ given in both the organic and inorganic form reveal substantial over-all loss of the bound isotope from sections subjected to contact with solvents prior to autoradiography. A comparison of autoradiograms prepared by dry-mounting sections of frozen-dried tissue with autoradiograms of wet-mounted sections of the same tissue suggest that the loss is proportional to the extent of the contact with solvents. Evidence suggests that loss of the isotope occurs during contact of the ribbon or section itself with solutions after fixation and cutting and prior to radiation exposure. No appreciable loss of the bound isotope seems to occur during contact of the intact tissue specimen with a variety of fluid fixatives except for a marginal zone at the excision edges of the tissue. The potential hazard of displacement of the isotope during fixation, however, remains. Technics which prevent loss of the isotope and fogging of the nuclear emulsion permit the use of thinner sections and emulsion films and the fine resolution of image rendered possible by the physical properties of S³⁵.     

The morphological and immunohistochemical analysis of renal biopsies by light and electron microscopy using a single processing method

A methodology is described in which a number of well-established research techniques are brought together to enable the complete diagnostic analysis of a renal biopsy on a single piece of tissue. By embedding the biopsy in the acrylic resin LR White, unsupported sections of which are stable in the electron beam, light and electron microscopy and immunocytochemistry become feasible on sections from the same block. The biopsy is glutaraldehyde fixed but post-fixation in osmium tetroxide, which is often deleterious to antigen preservation, is omitted. Extraction in organic solvents and resin monomer is minimized by rapidly infiltrating the tissue from 70% ethanol and polymerizing the resin catalytically at 0 degrees C. Semithin sections can be stained with haematoxylin and eosin, Toluidine Blue or methenamine silver, giving results similar or superior to those obtained from paraffin sections. Thin sections show that the standard of morphological preservation is similar to that seen using epoxide sections even though the kidney is unosmicated. The tissue retains a high level of antigen reactivity, which, in the limited number of cases so far examined, has paralleled or exceeded that demonstrated by conventional immunofluorescence on frozen sections.     

Gap junction structures. VIII. Membrane cross-sections.

Profiles of negatively stained gap junctions have been measured by grid sectioning. After normal levels of electron irradiation, the membrane thickness shrinks to about half that of unirradiated controls, but no shrinkage occurs in the hexagonal lattice plane. Even under low irradiation conditions, there is significant thinning of the membranes. Edge views, in which rows of connexons are aligned parallel to the beam, were obtained from grid sections, folds in normal negatively stained specimens, and sections of a positively stained specimen. Averaging these micrographs with the translational and mirror symmetry of the projected lattice image displays conserved and variable features in the stain distribution of different specimens. Variations in the relative amount of negative stain in the gap at the surfaces and in the channel are uncorrelated with the irradiation but appear to depend on the local staining conditions and the integrity of the connexons. The dimensions measured from previously unirradiated grid sections, folds, and positively stained sections are in accord with x-ray diffraction measurements. Radiation-induced shrinkage can be accounted for by mass loss principally from the membrane bilayer. Disordering of the surface structure appears to be correlated with the radiation sensitivity of the bilayer; in contrast, the gap structure is well preserved under a variety of conditions.     

Embedding Plant Tissue with Plastic Using High Pressure: A New Method for Light and Electron Microscopy

An embedding technique has been developed to overcome difficulties that confront light and electron microscopists working with so-called “hard-to-embed” plant tissue. The method was originally described for freeze-dried material. It uses a modified Quickfit Rotaflo Valve and low heat to generate high pressure to aid in the infiltration and embedding of tissue with propylene oxide and plastic. The technique is not too cumbersome and requires 6 days from the dehydration step to the end of the polymerization process. Thick sections (1-2 μm) obtained from material prepared by this method stain readily with toluidine blue, and thin sections for the electron microscope stain satisfactorily following standard treatment with uranyl acetate and lead citrate. The thin sections are stable under the beam of the electron microscope. Results indicate that the quality of tissue preservation with this high pressure embedding technique is as good as that observed using standard embedding methods for electron microscopy.     

Auto-radiographic determination of S35 in tissues after injection of methionine-S35 and sodium sulfate-S35

The loss of "bound" S(35) that occurs during various mounting procedures used in autoradiography was studied in healing surface wounds of rats treated with either methionine-S(35) or Na(2)S(35)O(4). Valid autoradiography of bound S(35) in this tissue is not possible until 48 hours after radiosulfate and 24 hours after radiomethionine injection, when the S(35) is almost entirely bound in large protein and polysaccharide molecules. Autoradiograms of S(35) given in both the organic and inorganic form reveal substantial over-all loss of the bound isotope from sections subjected to contact with solvents prior to autoradiography. A comparison of autoradiograms prepared by dry-mounting sections of frozen-dried tissue with autoradiograms of wet-mounted sections of the same tissue suggest that the loss is proportional to the extent of the contact with solvents. Evidence suggests that loss of the isotope occurs during contact of the ribbon or section itself with solutions after fixation and cutting and prior to radiation exposure. No appreciable loss of the bound isotope seems to occur during contact of the intact tissue specimen with a variety of fluid fixatives except for a marginal zone at the excision edges of the tissue. The potential hazard of displacement of the isotope during fixation, however, remains. Technics which prevent loss of the isotope and fogging of the nuclear emulsion permit the use of thinner sections and emulsion films and the fine resolution of image rendered possible by the physical properties of S(35).     

ELECTRON-PROBE X-RAY MICROANALYSIS: TECHNIQUES AND RECENT APPLICATIONS IN BIOLOGY

(1) X-ray microanalysis is a powerful technique, allowing the quantitative measurement of many elements of physiological interest, at physiological concentrations and with a spatial resolution typically of a few micrometres in bulk specimens, and a few hundred nanometres in thin sections. (2) The basic requirements are a focussed, high-energy electron beam, X-ray spectrometers and a means of visualizing the specimen. These facilities are found in a number of different types of commercial microanalysers, which may be based on either the transmission electron microscope, or the scanning electron microscope. Scanning microanalysers offer a lower image resolution, but are considerably more versatile than instruments based on the transmission electron microscope. (3) Preparing the specimen in a form that will withstand electron bombardment under high vacuum, and yet in which the elements to be analysed are retained in their original locations, is clearly the most critical step. For analysing diffusible elements, especially water-soluble electrolytes, the only reliable method is to freeze as rapidly as possible, and analyse the tissue without any chemical treatment. (4) The best results are obtained if frozen sections are cut and analysed on a cold-stage with their water content retained as ice. Procedures have been worked out for doing this, and for quantitative interpretation of the results, so that original tissue concentrations of the common electrolytes, phosphorus, sulphur and other elements of interest can now be measured with confidence. The original water-content of different cell and tissue compartments can also be estimated from the mass-loss on drying. (5) A simpler alternative is to freeze-dry the frozen sections before analysis. The distribution of diffusible elements is probably not too much disturbed, spatial resolution is improved, and the visual image becomes much clearer, but quantitation is made more difficult and less reliable. Nevertheless this technique is frequently used. (6) For precipitated materials and for fluid samples, much simpler methods of preparation can be used. (7) The technique is the subject of a large and rapidly expanding literature, and is providing new information on the sub-cellular distribution of electrolytes and other elements in many different tissues from animals and plants. (8) Some of the earliest applications to the study of diffusible ions were in the analysis of micropuncture samples from kidney tubules, where it has been possible to analyse many very small samples, and for several elements at once. Some preliminary information has also been obtained on the intracellular ion concentrations in kidneys subjected to different physiological conditions. (9) A particularly successful field has been the study of transporting epithelia, including vertebrate and insect digestive and excretory tissues, where the distribution of ions along the intercellular spaces has been shown not to agree with that predicted from the ‘standing gradient’ theory of osmotic coupling. The regulatory mantle epithelium in a mollusc has also been investigated, and some new information obtained on intracellular ion distributions in the frog skin. (10) Studies on nervous tissue are still at a preliminary stage, because of the structural complexity of the tissue. In muscle, however, it has been possible to demonstrate the re-uptake of calcium by intracellular structures, following its release into the cytoplasm during contraction. (11) Information has been obtained on the distribution of ions in the nuclei and chromosomes of cells at different stages in development and division. Nuclear sodium and potassium levels are generally similar to those in the cytoplasm: the very high sodium concentrations found in nuclei isolated anhydrously are shown to be artefactual. (12) A variety of plant cells has been investigated, problems of particular interest being the regulation of salt uptake by roots and leaves, and the role of potassium ions in causing opening of the stomata by osmotic swelling of the guard-cells. (13) Some applications in pathology are briefly mentioned, including studies on the fate of accidentally or deliberately introduced minerals, and on differences in the ion content of normal and diseased muscle cells. (14) Numerous observations on the subcellular distribution of calcium are collected together. In general, measurable calcium uptake by mitochondria appears to occur only in damaged cells; in muscle the cell-membrane and the sarcoplasmic reticulum seem to be the main organelles responsible for re-uptake of calcium following a contraction. Direct involvement of calcium with a contractile system has been shown in the vorticellid protozoan Zoothamnium, and a connection between calcium and exocytosis has been demonstrated in digestive and other epithelia.     

Investigation of viability of plant tissue in the environmental scanning electron microscopy

The advantages of environmental scanning electron microscopy (ESEM) make it a suitable technique for studying plant tissue in its native state. There have been few studies on the effects of ESEM environment and beam damage on the viability of plant tissue. A simple plant tissue, Allium cepa (onion) upper epidermal tissue was taken as the model for study. The change of moisture content of samples was studied at different relative humidities. Working with the electron beam on, viability tests were conducted for samples after exposure in the ESEM under different operating conditions to investigate the effect of electron beam dose on the viability of samples. The results suggested that without the electron beam, the ESEM chamber itself can prevent the loss of initial moisture if its relative humidity is maintained above 90%. With the electron beam on, the viability of Allium cepa (onion) cells depends both on the beam accelerating voltage and the electron dose/unit area hitting the sample. The dose can be controlled by several of the ESEM instrumental parameters. The detailed process of beam damage on cuticle-down and cuticle-up samples was investigated and compared. The results indicate that cuticular adhesion to the cell wall is relatively weak, but highly resistant to electron beam damage. Systematic study on the effect of ESEM operation parameters has been done. Results qualitatively support the intuitive expectations, but demonstrate quantitatively that Allium cepa epidermal cells are able to be kept in a hydrated and viable state under relevant operation condition inside ESEM, providing a basis for further in situ experiments on plant tissues.     

IN VIVO AND IN VITRO OBSERVATIONS OF LEPTOSPIRA POMONA BY ELECTRON MICROSCOPY.

Miller, Norman G. (University of Nebraska College of Medicine, Omaha) and Richard B. Wilson. In vivo and in vitro observations of Leptospira pomona by electron microscopy. J. Bacteriol. 84:569-576. 1962.-Leptospira pomona 3341 was observed by electron microscopy, after the preparation of thin sections from culture material and from infected hamster tissue. The external membrane of low electron density envelops the entire leptospire and appears to be quite flexible, as suggested by its many folds. The spiral protoplasmic body is tubular in structure with a relatively dense wall and a central area of low electron density. Occasionally, very dark circumscribed bodies were seen imbedded in the protoplasmic wall. Detailed morphology is presented of a knoblike structure located at the end of the axial filament. Bifurcation of the axial filament could be demonstrated in leptospires from cultures. Leptospires were observed free or enclosed in vesicles within the cytoplasm of liver parenchymal and renal tubule cells. Erythrocytes located in kidney tissue also contained leptospires within the cytoplasm. The appearance of intracellular leptospires is much the same as those seen extracellularly or from culture.     

THE USE OF SPECIFIC ANTIBODY IN ELECTRON MICROSCOPY : II. The Visualization of Mercury-Labeled Antibody in the Electron Microscope

Glycerinated chicken muscle was stained with antimyosin antibody conjugated with mercury and fluorescein. The antibody was visualized in both the electron and the fluorescence microscope by using adjacent thin and thick sections. In order to make this possible, Araldite was used as the embedding medium. The mercury was reduced to metallic mercury in the electron beam and either migrated in the section or was sublimated in the vacuum. Therefore special techniques of carbon filming had to be used to prevent this. Some nonspecific staining occurred because of the binding of mercury to available sulfhydryl groups in the tissue. The available sulfhydryl groups were blocked by pretreating the tissue with iodoacetic acid and formaldehyde. The non-specific staining which occurred after this treatment was easily removed by brief washing with a buffered solution of thioglycolic acid.     

Electron density imaging of protein films on gold-particle surfaces with transmission electron microscopy

BACKGROUND: Surface bound proteins on colloid particles are widely used in biotechnological applications such as diagnostics or separation. Analysis of colloid surfaces by imaging methods provides information on the structure of these protein films, and an understanding of the functional relationships of biomolecules immobilised on solid surfaces. METHODS: In order to visualise protein molecules organised in films on surfaces of nano-sized gold-particles, an electron-microscopic approach based on the scattering absorption contrast of the specimen was applied. RESULTS: Analysing protein conjugated gold particles with a transmission electron microscope, protein films on gold particle surfaces cause a significant scattering absorption contrast based on the materials' electron density. Thus, the thickness of such films becomes directly measurable in planar projection and the shape of these films are visualised without negative staining methods. The insertion of Ruthenium-labelled antibodies instead of non-labelled antibodies as a marker with increased electron-density in these films yields a contrast enhancement of the whole film. Additional labelling with anti-Mouse IgG Gold conjugates localises the position of the surface bound antibodies in such protein films. CONCLUSIONS: The power of transmission electron microscopy to resolve protein-films on colloid surfaces without staining or labelling as a sample preparation procedure has been demonstrated. Thus, this direct method provides an analytical tool for studying protein films and their structural features on particle surfaces.     

Complete penetration of antibodies into vibratome sections after glutaraldehyde fixation and ethanol treatment: light and electron microscopy for neuropeptides.

To develop a method for quantitative electron microscopic immunocytochemistry on neural tissue of CNS, we tested the extent to which ethanol treatment would improve the penetration of immunoreagents through vibratome sections fixed in high concentrations of glutaraldehyde without compromising ultrastructure. Transverse or sagittal vibratome sections (60-80 microns) of spinal cord perfused with 1% formaldehyde plus 1% or 2.5% glutaraldehyde were washed in 50% ethanol for 0-70 min and stained to reveal immunoreactivity for neuropeptide Y (NPY). Semi-thin (1 micron) or ultra-thin sections were used to assess the depth to which NPY nerve fibers in the dorsal horn were stained. Without ethanol washing, immunoreactive nerve fibers were visualized only in the surface 5-10 microns of transverse or sagittal vibratome sections. In transverse vibratome sections, NPY nerve fibers, which ran perpendicular to the cut surfaces of the sections, were entirely stained after a 30-min wash in 50% ethanol. The numbers of NPY-immunoreactive varicosities and synapses were comparable at the surfaces and in the centers of the vibratome sections. In sagittal sections, where NPY nerve fibers ran parallel to the cut surfaces, fibers in the centers of vibratome sections could not be labeled even after 70 min in 50% ethanol. Substance P- and enkephalin (Enk)-immunoreactive nerve fibers could also be completely stained in transverse sections of spinal cord or medulla oblongata after 30-min exposure to ethanol. Ethanol washing had no significant deleterious effects on ultrastructure, although the amount of cytoplasmic matrix in neurons decreased with increasing exposure. These results indicate that washing with 50% ethanol for at least 30 min allows immunoreagents to penetrate completely through nerve fibers fixed with high concentrations of glutaraldehyde, as long as the fibers have cut ends at both surfaces of a vibratome section. This technique makes possible quantitative electron microscopic immunocytochemical studies and is proving a useful tool for defining synaptic connections in the CNS.     

Penetration of Stain in Ultrathin Sections of Tobacco Mosaic Virus

Purified preparations of tobacco mosaic virus (TMV) and pieces of tomato leaves infected with TMV were embedded in methacrylate or epoxy resin, sectioned, and stained with 1.0% strontium permanganate for electron microscopy. In sections containing purified and intracellular virus, the apparent length of stained particles varied directly with section thickness, indicating stain penetration beyond the surface of the section. Penetration was demonstrated also by stereoscopy. Penetration was less complete when sections were allowed to dry before staining. In most instances the number of identifiable particles per unit area was independent of section thickness but increased when both surfaces of the sections were stained instead of only one surface. Staining was prevented by thin films of methacrylate or epoxy resin placed between the virus section and staining solution. Most results supported the view that electron scattering capacity was enhanced only in particles which intersected the surface of the section exposed to permanganate.     

Pituitary Secretory Granule Topography: Influence of Different Electron Microscopic Preparation Procedures on the Surface of Epon Sections

Human, rat and mouse pituitary tissues have been examined electron microscopically in transmission (TEM), scanning-transmission (STEM) and scanning (SEM) modes for the surface appearance of the secretory granules in tissue sections. Cryofixed and cryosectioned tissue showed only slightly protruding granule profiles which had a smooth surface. Cryofixed, freeze-dried and Epon embedded pituitaries, on the other hand, demonstrated swollen and furrowed surfaces over the granules after contact with water. This topography could also be seen after glutaraldehyde fixation but less after post-fixation in OsO₄. The surface alterations in the sections of pituitary secretory granules are thought to be due to differences in the homogeneity of the resin infiltration, leaving resin-free openings where water can enter. It also seems probable that the Epon resin is more influenced by water than has been previously assumed, based on the findings of efficient elimination of osmium from the granules after incubation of tissue sections in water for only 10 min.     

Pituitary Secretory Granule Topography: Influence of Different Electron Microscopic Preparation Procedures on the Surface of Epon Sections

Human, rat and mouse pituitary tissues have been examined electron microscopically in transmission (TEM), scanning-transmission (STEM) and scanning (SEM) modes for the surface appearance of the secretory granules in tissue sections. Cryofixed and cryosectioned tissue showed only slightly protruding granule profiles which had a smooth surface. Cryofixed, freeze-dried and Epon embedded pituitaries, on the other hand, demonstrated swollen and furrowed surfaces over the granules after contact with water. This topography could also be seen after glutaraldehyde fixation but less after post-fixation in OsO₄. The surface alterations in the sections of pituitary secretory granules are thought to be due to differences in the homogeneity of the resin infiltration, leaving resin-free openings where water can enter. It also seems probable that the Epon resin is more influenced by water than has been previously assumed, based on the findings of efficient elimination of osmium from the granules after incubation of tissue sections in water for only 10 min.     

IDENTIFICATION OF GLYCOGEN IN ELECTRON MICROGRAPHS OF THIN TISSUE SECTIONS

The electron microscopic appearance of glycogen has been studied in the organs of several animal species. Glycogen almost always appears as roughly circular granules from 150 to 400 A in diameter. The intrinsic electron density of glycogen varies from tissue to tissue; however, treatment with lead hydroxide as described by Watson deeply stains the granules. Glycogen pellets were isolated from some of the tissues studied by centrifugation. Such pellets were shown to be glycogen by chemical and histochemical criteria. When thin sections of the pellet are examined under the electron microscope they can be seen to consist of densely packed granules similar to those found in the intact tissues. Such pellets are also stained for electron microscopy by short exposure to lead hydroxide.     

Autoradiography of Mobile, C14-Labeled Herbicides in Sections of Leaf Tissue

Fresh leaf tissue containing a soluble, C¹⁴-labeled herbicide was mounted in cold 1% gelatin on a holder, quick frozen in a cryostat, and cross sectioned at 16 μ with single-edge, stainless steel razor blades. The sections were transferred (without thawing) to cold (—10 C) microscope slides which had been partly covered with double-coated Scotch tape #665. The tissue was freeze-dried in a vacuum desiccator at—20 C then secured to the tape with pressure. Autoradiography was accomplished in a darkroom by covering the slides with dry, nuclear track emulsion films. These films were made by dipping 2 inch diameter wire loops into liquid emulsion, letting the film dry, and applying it by blowing it as it was placed against the tissue. After a 19 day exposure in light-tight boxes at 25-27 C the preparations were processed in the usual manner. The method-was used successfully to trace the movement of soluble, C¹⁴-labeled herbicides in leaf tissue without the loss of labeling material or artifacts caused by its diffusion. High resolution autoradiograms with low backgrounds were obtained.