Lanthanum as an electron microscopic stain

Applications of lanthanum as an electron microscopic tracer have been reviewed. This electron-dense trivalent cation, which binds avidly to calcium binding sites, can be used as tracer for delineating extracellular spaces and intercellular junctions. It has served as a basis for classification of junctional structures. It can also be used as a calcium probe, a tracer in studying the permeability of barriers, as an intracellular marker and as an electron microscopic stain for such membrane components as surface glycoprotein. Each of these applications may require a different methodology. Thus methodological considerations in the use of this tracer have also been reviewed. The recent recognition that lanthanum is more than a passive tracer and that by reacting with different cell components may serve as a true stain, will extend the use of lanthanum in electron microscope histochemistry.     

Ultrastructural observations on tissues processed by a quick-freezing,rapid-drying method: Comparison with conventional specimen preparation

A quick-freeze, rapid-dry method for processing unfixed tissue for electron microscopy has been developed. The technique employs freezing on a cryogenchilled metal surface and drying in a cryosorption vacuum apparatus that allows osmium-vapor fixation and epoxy-resin embedment under high vacuum. Liver, kidney, bone marrow, and monolayer cultures of ventricular myocytes were selected as tissue specimens representing a wide range of physical properties, to demonstrate the practical aspects of achieving good ultrastructural morphology by freeze drying. A comparison was made between freeze drying and conventional processing using aldehyde fixation and alcohol dehydration. The preservation of cellular ultrastructure achieved by freeze drying allowed the identification of specific cell types within each specimen. Membranous organelles were well preserved, surrounded by cytoplasmic ground substance devoid of ice crystal damage. Electron-dense material was observed within the rough endoplasmic reticulum and Golgi cisternae and vesicles of frozen-dried, but not conventionally processed cells. This suggests the preservation by freeze drying of cytoplasmic components otherwise extracted from the cell by solvent exposure.     

Tannic Acid as an Electron Microscope Tracer for Permeable Cell Membranes

To recognize damaged cells in preparations for transmission electron microscopy, high molecular weight (1700 MW) tannic acid (1-4%) has been added to glutaraldehyde fixing solutions. During fixation, the tannic acid penetrates only those cells whose plasma membranes were previously damaged. It enhances the electron density of the injured cells, which become clearly distinguishable from the undamaged ones. As a tracer tannic acid shows great advantages over either lanthanum hydroxide, ruthenium red, or horseradish peroxidase. It diffuses evenly throughout the tissue block and is not removed by preparative steps. Furthermore, it is also a good tracer at the light microscope level.     

A method for staining actin-containing structures in thick plastic sections for medium voltage electron microscopy

A staining procedure has been developed for imaging actin-containing structures in thick plastic sections in the electron microscope. The stress fibres of a fibroblastic cell line were used as a model system, and were first characterized immunocytochemically. After fixation of cells in formaldehyde, mordanting in a solution of gadolinium chloride allows stress fibres to be stained for light microscopy with haematoxylin. A brief exposure to a solution of ammonium paramolybdate renders haematoxylin-stained structures sufficiently electron-dense to be imaged in 1 micron thick plastic sections in a JEOL 200CX electron microscope, operating at 200 kV, and possibly in conventional instruments operating at 100 kV, particularly if equipped with a lanthanum hexaboride source.     

The Apoplastic Pathway of Transport to Salt Glands

The availability of the apoplastic route for ion transport tosalt glands was assessed by electron microscope examinationsand by the use of lanthanum as an electron-dense tracer to demarcatethe apoplast. The results show that this solute can reach thesalt glands via the apoplast and this observation is discussedin relation to current ideas concerning salt gland function.     

Out with the old and in with the new: rapid specimen preparation procedures for electron microscopy of sectioned biological material

This article presents the best current practices for preparation of biological samples for examination as thin sections in an electron microscope. The historical development of fixation, dehydration, and embedding procedures for biological materials are reviewed for both conventional and low temperature methods. Conventional procedures for processing cells and tissues are usually done over days and often produce distortions, extractions, and other artifacts that are not acceptable for today’s structural biology standards. High-pressure freezing and freeze substitution can minimize some of these artifacts. New methods that reduce the times for freeze substitution and resin embedding to a few hours are discussed as well as a new rapid room temperature method for preparing cells for on-section immunolabeling without the use of aldehyde fixatives.     

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)     

Optimization of immunogold labeling TEM. An ELISA-based method for rapid and convenient simulation of processing conditions for quantitative detection of antigen.

We developed an ELISA-based method for rapid optimization of various tissue processing parameters in immunogold labeling for electron microscopy. The effects of aldehyde fixation, tannic acid, postfixation, dehydration, temperature, and antigen retrieval on antibody binding activity of Vitreoscilla hemoglobin (VHb) expressed in E. coli cells were assayed by ELISA and the results confirmed by quantitative immunogold labeling transmission electron microscopy (TEM). Our results demonstrated that low concentrations (0.2%) of glutaraldehyde fixation caused minimal loss in total binding compared to higher concentrations. Dehydration in up to 70% ethanol resulted in some distortion of cellular ultrastructure but better antibody binding activity compared to dehydration up to 100%. Postfixation or incorporation of tannic acid in the primary fixative caused almost total loss of activity, whereas antigen retrieval of osmium-postfixed material resulted in approximately 90-100% recovery. The sensitivity of detection of proteins by immunogold labeling electron microscopy depends on the retention of antibody binding activity during tissue processing steps, e.g., fixation and dehydration. Our study indicated that an ELISA-based screening method of various tissue processing procedures could help in rapid selection and optimization of a suitable protocol for immunogold localization and quantification of antigen by TEM.     

Comparison between direct methods for determination of microbial cell volume: electron microscopy and electronic particle sizing.

Size frequency distributions of different phototrophic and heterotrophic microorganisms were determined by means of scanning and transmission electron microscopy and electronic particle sizing. Statistically significant differences existed among the three techniques used in this study. Cells processed for electron microscopy showed lower mean cellular volumes than those processed for electronic particle sizing, reflecting a shrinkage by factors ranging from 1.1 to 6.2 (mean, 2.3). Processing of cells for scanning electron microscopy caused higher shrinkage than processing for transmission electron microscopy. Shrinkage was dependent neither on the size nor on the cell wall type of the microorganism. When processed for scanning electron microscopy, phototrophic bacteria were strongly shrunken, whereas heterotrophic microorganisms were less affected. A direct relationship existed among phototrophic bacteria between percentage of shrinkage and specific pigment content. This was probably a consequence of the pigment extraction by organic solvents during the dehydration process, previous to the critical point drying, necessary to examine the specimens under the scanning electron microscope.     

Electron microscopy of lanthanum in plasma

Summary Aqueous solutions of lanthanum nitrate may be used as electron microscopic tracers in vivo to study vascular permeability in the experimental animal. However, with this technique the size of the tracer particles is not known. To gain information about the tracer size, we injected lanthanum nitrate into the blood circulation of living rabbits. The plasma obtained from such animals 30 min later, was studied with the electron microscope. The plasma contained an electron-dense material, readily visible in the electron microscope. A precipitate obtained after centrifugation of the whole blood to separate the cells, also contained the tracer. Lanthanum was found in large amounts in the fibrin clot obtained after treating the plasma with thrombin. The tracer was not detected in the serum (i.e. thrombin-treated plasma). The study indicates that ionic lanthanum injected into the blood circulation of living rabbits, is to a great extent bound to fibrinogen, and that the smallest possible size of the tracer is that of the fibrinogen,molecule (m. w. 330,000). Larger particles are present as well.     

Freeze-fracture electron microscopy

The freeze-fracture technique consists of physically breaking apart (fracturing) a frozen biological sample; structural detail exposed by the fracture plane is then visualized by vacuum-deposition of platinum-carbon to make a replica for examination in the transmission electron microscope. The four key steps in making a freeze-fracture replica are (i) rapid freezing, (ii) fracturing, (iii) replication and (iv) replica cleaning. In routine protocols, a pretreatment step is carried out before freezing, typically comprising fixation in glutaraldehyde followed by cryoprotection with glycerol. An optional etching step, involving vacuum sublimation of ice, may be carried out after fracturing. Freeze fracture is unique among electron microscopic techniques in providing planar views of the internal organization of membranes. Deep etching of ultrarapidly frozen samples permits visualization of the surface structure of cells and their components. Images provided by freeze fracture and related techniques have profoundly shaped our understanding of the functional morphology of the cell.     

FITC-Dextran tracers in microcirculatory and permeability studies using combined fluorescence stereo microscopy,fluorescence light microscopy and electron microscopy

Summary Coupling fluorescein-isothiocyanate to dextrans (FITC-D) extends the usefulness of the dextrans as electron microscopic tracer particles by permitting preceding fluorescence stereo microscopy and high-power light microscopy of the tissue specimens. The fate of the tracer may thus be studied in vivo during the experiment, during fixation, and during the succeeding tissue processing. A study of some simple physicochemical characteristics of the tracer, and the influence, if any, of the fixing agent are also made possible. FITC-D was found to be uncharged in the pH range from 6.5 to 8.5, more rapidly precipitated by acetone than by alcohol, and to react with glutaraldehyde and osmium tetroxide in an unknown way during tissue fixation. FITC-D with molecular weights 70,000 and 150,000 showed no signs of diffusion during tissue preparation with the methods reported in the paper, whereas FITC-D 40,000 did so to a slight degree, when the tissue was kept for several days in the fixative vehicle. Securing the preservation of the lower molecular weight FITC-Ds during tissue fixation and preparation is more difficult and the described methods are not adequate. Dextrans provoke an anaphylactic reaction in most rat strains, but are well tolerated by Wistar Furth rats. The introduction of FITC into the dextran molecule might alter the biological reactions, but was also well tolerated by Wistar Furth rats. Combined fluorescence stereo microscopy, fluorescence microscopy of sections, light microscopy of stained sections and electron microscopy made it possible to follow a particular microcirculatory area, selected in vivo, to the final study in the electron microscope.     

Preservation of arachidonoyl phospholipids during tissue processing for electron microscopic autoradiography

To facilitate autoradiographic subcellular localization of arachidonoyl phospholipids, the retention of radioactivity during tissue processing of murine fibrosarcoma cells labeled in vitro with 3H-arachidonate was assessed. Approximately 94% of cell radioactivity was incorporated into phospholipids. During tissue processing, extraction of radioactivity was monitored by liquid scintillation spectrometry. Fixation of cells in glutaraldehyde-tannic acid, postfixation in osmium tetroxide, en bloc staining in uranyl magnesium acetate, dehydration in ethanol, and embedding in Epon resulted in preservation of 93.5% of total tissue radioactivity. Analysis of extracted radioactivity by thin layer chromatography revealed that no specific class of phospholipids was selectively extracted. Fixation with osmium tetroxide alone was nearly as effective as the complete fixation protocol and resulted in retention of 90.0% of radioactivity. However, fixation with glutaraldehyde-tannic acid alone without osmium tetroxide post-fixation led to extraction of 69.8% of total cell radioactivity. Thus, osmium tetroxide is crucial in the preservation of arachidonoyl phospholipids and presumably forms extensive cross-links between polyunsaturated acyl residues. This degree of preservation of arachidonoyl phospholipids is indicative of spatial fixation of the radiolabeled moieties and will permit quantitative studies of subcellular loci of eicosanoid metabolism by electron microscopic autoradiography.     

FITC-dextran tracers in microcirculatory and permeability studies using combined fluorescence stereo microscopy, fluorescence light microscopy and electron microscopy

Coupling fluorescein-isothiocyanate to dextrans (FITC-D) extends the usefulness of the dextrans as electron microscopic tracer particles by permitting preceding fluorescence stereo microscopy and high-power light microscopy of the tissue specimens. The fate of the tracer may thus be studied in vivo during the experiment, during fixation, and during the succeeding tissue processing. A study of some simple physicochemical characteristics of the tracer, and the influence, if any, of the fixing agent are also made possible. FITC-D was found to be uncharged in the pH range from 6.5 to 8.5, more rapidly precipitated by acetone than by alcohol, and to react with glutaraldehyde and osmium tetroxide in an unknown way during tissue fixation. FITC-D with molecular weights 70,000 and 150,000 showed no signs of diffusion during tissue preparation with the methods reported in the paper, whereas FITC-D 40,000 did so to a slight degree, when the tissue was kept for several days in the fixative vehicle. Securing the preservation of the lower molecular weight FITC-Ds during tissue fixation and preparation is more difficult and the described methods are not adequate. Dextrans provoke an anaphylactic reaction in most rat strains, but are well tolerated by Wistar Furth rats. The introduction of FITC into the dextran molecule might alter the biological reactions, but was also well tolerated by Wistar Furth rats. Combined fluorescence stereo microscopy, fluorescence microscopy of sections, light microscopy of strained sections and electron microscopy made it possible to follow a particular microcirculatory area, selected in vivo, to the final study in the electron microscope.     

Techniques to preserve soluble surface components in birch pollen wall: a scanning and transmission electron microscopic study

The exine of birch pollen was examined by scanning and transmission electron microscopy in the native state and after fixation in different aqueous fixatives: glutaraldehyde + OsO4; glutaraldehyde + cetylpyridinium chloride (CPC) + OsO4; glutaraldehyde + cuprolinic blue (CB); and periodate + lysine + paraformaldehyde (PLP). The native pollen exine showed a thin (3-5-nm) border of electron-dense material lining the tectum and electron-dense material within microchannels and bacula cavities. Fixation with the addition of CPC resulted in a voluminous surface coat surrounding the pollen grain, but empty microchannels and bacula cavities. After fixation with the addition of CB, there was a thin surface coat, whereas microchannels and bacula cavities were partially filled with electron-dense material. The other fixatives led to empty microchannels and bacula cavities. There was no surface coat on the pollen grain. However, after all fixation procedures, a thin electron-dense border of the tectum remained visible. Concerning the electron-dense material filling microchannels and bacula cavities in the native pollen grain, the results obtained in the present study suggest that it is either completely lost (after conventional and PLP fixation) or, after fixation with a precipitating additive, partially (CB) or completely (CPC) solubilized and precipitated on the surface of the pollen grain as a surface coat.     

Permeability of the haemolymph-neural interface in the terrestrial snail Megalobulimus abbreviatus (Gastropoda, Pulmonata): an ultrastructural approach

The aim of this study was to investigate the ultrastructure of the interface zone between the nervous tissue and the connective vascular sheath that surround the central ganglia of the terrestrial snail of Megalobulimus abbreviatus and test its permeability using lanthanum as an electron dense tracer. To this purpose, ganglia from a group of snails were fixed by immersion in a 2% colloidal lanthanum solution, and a second group of animals was injected in the foot with either a 2%, 10% or 20% lanthanum nitrate solution and then sacrificed 2 or 24 h after injection. Ganglia from both groups were processed for transmission electron microscopy. The vascular endothelium, connective tissue and basal lamina of variable thickness that ensheathe the nervous tissue and glial cells of the nervous tissue constitute the interface zone between the haemolymph and the neurones. The injected lanthanum reached the connective tissue of the perineural capsule; however, it did not permeate into the nervous tissue because the basal lamina interposed between both tissues interrupted this passage. Moreover, the ganglia fixed with colloidal lanthanum showed electron dense precipitates between the glial processes in the area adjacent to the basal lamina. It can be concluded from these findings that, of the different components of the haemolymph-neuronal interface, only the basal lamina, between the perineural capsule and the nervous tissue, limits the traffic of substances to and from the central nervous system of this snail.     

Rapid fixation and embedding for electron microscopy

A method has been developed for rapid processing of animal tissues for electron microscopy. The whole process of fixation staining dehydration, infiltration and embedding including polymerization is completed in less than 4 hr. A variety of human and animal tissues such as liver, spleen, muscle, kidney and embryonic chick heart were processed by this method and the results were excellent. The rapid fixation and embedding method is strongly recommended when relatively soft tissues are to be studied. This method is especially useful for examining pathological tissues for rapid diagnostic purposes.     

A new method of preparing insects for scanning electron microscopy.

Acidified 2,2-dimethoxypropane (DMP), used as an alternative to regular fixation and dehydration methods for insects, was found to be the only successful means of preparing the sugarbeet root maggot larva, Tetanops myopaeformis (R?der) (Diptera:Otitidae), for the scanning electron microscope. No morphological changes were evident when DMP treated sugarbeet root maggot adults were compared to fresh (unfixed) adults and glutaraldehyde-osmium tetroxide fixed adults. The method has been used with success on several gropus of insects. Acidified CMP is quickly hydrolyzed by water in tissue to acetone and methanol. DMP is advantageous in that it penetrates water impermeable cuticles rapidly and saves several steps and time in the fixation and dehydration process.     

Scanning and transmission electron microscopic studies of jejunal microvilli of the rat, hamster and dog

Scanning and transmission electron microscopy were used to investigate the surface area and number per unit area of microvilli from jejunal villus epithelial cells in the rat, hamster and dog. The calculated mean microvillus surface area was 0.419 μ², 0.573 μ², 0.751 μ² for the rat, hamster and dog respectively. The largest number of microvilli per square micron freeze dried villus surface was measured in the rat with a mean value of 65. Hamster and dog freeze dried specimens had lower mean values of 54 and 34 microvilli respectively. The total microvilli surface area in square micron per square micron villus surface was more closely related for the three species with values of 27.23 for the rat, 30.94 for the hamster and 25.53 for the dog. These data indicate an inverse relationship between the mean microvillus surface area and population density in the species studied. However, the total microvilli surface area per unit villus surface is relatively similar for the three species. The observed number of microvilli per unit villus surface was shown to vary depending upon the dehydration technique employed for preparation of scanning electron microscopic specimens. This variation probably reflects shrinkage artifact and should be considered in soft tissue studies involving the scanning electron microscope.     

Simultaneous localization of proteoglycan by light and electron microscopy using toluidine blue O. A study of epiphyseal cartilage.

The simultaneous localization of proteoglycan by light and electron microscopy was demonstrated by fixing epiphyseal cartilage in a glutaraldehyde toluidine blue O solution. Sections cut for light microscopy viewing and those cut for electron microscopy required no further staining, although, in the latter case, staining with uranyl acetate and lead improved the overall contrast. By this technique, electron-dense structures were seen concentrated about the cells which were actively synthesizing matrix, and these structures appeared to bind collagen fibrils. Similar structures were not seen in conventionally fixed tissue. They could also not be identified when the specimens were previously incubated with the proteoglycan-digesting enzyme, papain, prior to toluidine blue O fixation. The toluidine blue O fixation method, unlike conventional fixation and staining, retained proteoglycan in the pericellular areas of actively synthesizing cells and made it visible by light and electron microscopy. It appears that proteoglycans is both precipitated and stained by the presence of toluidine blue O during fixation.