The influence of embedding media and fixation on the postembedment ultrastructural demonstration of complex carbohydrates. III. High iron diamine staining for sulfated glycoconjugates

The high iron diamine (HID) method for detection of sulfated complex carbohydrate has been applied directly on thin sections of variably fixed tissues embedded in epoxy and nonepoxy resins. Results with postembedment HID staining in mouse intestinal epithelium are compared to those previously obtained using preembedment methods. Sections from epoxy-embedded tissues have been found to exhibit the weakest staining intensity. Intense, specific staining was obtained in tissues not postfixed with osmium tetroxide and embedded in polystyrene, polyester resins, styrene-methacrylate, and especially the styrene-Vestopal W embedding mixture. Postosmication of tissues abolished HID staining in epoxy resins and the styrene-Spurr's resin embedding mixture, but only reduced the staining intensity in tissues embedded in nonepoxy resins.     

Sheet Mica—A Nonadherent Carrier for Surface Culture of Cells to Be Embedded in Epon

With epoxy resins as embedding media, more richness in detail in electron micrographs can be gained than with methacrylate. For the embedding of surface-cultured cells, however, the use of Epon has been impractical because it cannot be readily separated, after hardening, from the glass surfaces on which cells are usually cultured.     

Epoxy-slide embedment of cytochemically stained tissues and cultured cells for light and electron microscopy

A new method is described for embedding stained tissue sections, cells, cultured cells or organ cultures in a special polyethylene mold to form epoxy microscope slides (cast-a-slides). Cast-a-slides in which biological specimens are embedded may be examined by light microscopy and individual optimally stained cells or tissue areas selected for examination by various modes of electron microscopy or X-ray microanalysis. Cultured cells or organs can be grown, fixed, stained and embedded in epoxy in the same cast-a-slide mold. The cast-a-slides can be stored conveniently in the same manner as glass microscopy slides.     

Epoxy-Slide Embedment of Cytochemically Stained Tissues and Cultured Cells for Light and Electron Microscopy

A new method is described for embedding stained tissue sections, cells, cultured cells or organ cultures in a special polyethylene mold to form epoxy microscope slides (cost-a-slides). Cast-a-slides in which biological specimens are embedded may be examined by light microscopy and individual optimally stained cells or tissue areas selected for examination by various modes of electron microscopy or X-ray microanalysis. Cultured cells or organs can be grown, fixed, stained and embedded in epoxy in the same cast-a-slide mold. The cast-a-slides can be stored conveniently in the same manner as glass microscopy slides.     

AFM of biological material embedded in epoxy resin

We present a simple method to extract morphological details from the block face of epoxy embedded biopolymers by AFM. It is shown that topographical contrast and the identification of small structural details critically depend on the procedure of sample preparation before embedding (chemical fixation or high-pressure freezing and freeze-substitution) and on the hardness of the embedding epoxy resin. Ethanol treatment of the block face of the sample after microtomy elutes non-cross-linked polymer chains and makes the smallest details of the embedded biomaterial amenable to detection. AFM (height and phase contrast) examination of the block face of accordingly prepared cells of Caenorhabditis elegans provides data that are comparable to TEM.     

Millipore Filtration of Conjugating Bacterial Cells, with Epoxy Embedding for Electron Microscopy

Broth cultures of Escherichia coli, strains Hfr G6 and F^- 464 grown separately, were mixed (2 ml of each) and the mixture filtered through a 0.45 μ pore size, 25 mm diameter, MF-Millipore membrane. The membrane was placed, cell side up, on a nutrient agar plate and incubated 15 min at 37 C. Processing in the customary manner to include fixation, staining and epoxy embedding for electron microscopy followed. The technique provides greater concentration of cells, allows less opportunity for separation of conjugating cells and is less time consuming than procedures involving concentration by centrifugation and enclosure in agar as prerequisities to resin embedding.     

Use of anti-fluorophore antibody to achieve high-sensitivity immunolocalizations of transporters and ion channels.

We have discovered that the immunoreactivity of the fluorophore Alexa Fluor 488 survives glutaraldehyde and osmium tetroxide fixation and epoxy resin embedding and etching. We have developed new localization methods that for the first time take advantage of this property. The antigen is localized in cryosections using suitable primary antibody and an Alexa Fluor 488-conjugated secondary antibody. Cryosection fluorescence can be photographed for later correlation with electron microscopy (EM) findings. The sections are then further fixed with glutaraldehyde and OsO4, if desired and flat-embedded in epoxy resin. Semi-thin sections are etched completely with sodium ethoxide, whereas thin sections are partially etched. Alexa Fluor 488 is then localized with rabbit anti-Alexa Fluor 488 and goat anti-rabbit conjugated to Alexa Fluor 488 [light microscopy (LM)] or to colloidal gold (EM). A second antigen may also be localized using Alexa Fluor 568. When used without postfixation, these methods produce high-resolution semi-thin, or even thin, sections that retain a high level of fluorescence for LM observations. These methods allow highly sensitive immunolocalizations in tissue while preserving cell fine structure through traditional fixation and epoxy embedding. In demonstration of the methods, we describe the localization of the thiazide-sensitive sodium/chloride cotransporter and the epithelial sodium channel in rat kidney.     

A Device for Flat-Face, Epoxy Resin Embedding of Tissues and Coverslip Cultures

An easily constructed device permits the flat-face embedding of four specimens in epoxy resins. Either pieces of tissue or cells grown on cover slips can be used. After polymerization, the flat-surfaced capsules may be examined under high magnification for selection of areas to be sectioned. Specimens difficult to orient can be cut out and re-embedded in the proper position. The use of thick-walled BEEM capsules and the clamping action afforded by four screws prevent leakage of the resin.     

A novel tight cylindrical mold for epoxy resin embedding allows enhanced microscopic analysis of microcores extracted from woody plants

A novel mold was devised to embed microcores extracted from stems of trees in epoxy resin, which has been widely used for optical and electron microscopic analysis of xylem formation. The embedding mold of a tight cylindrical shaped tube was designed to avoid displacement of microcores from the right position during the process of resin embedding. Microcores of a ring-porous hardwood species, Quercus crispula, with higher wood density and much larger differentiating vessel elements laid down on the boundary between the current xylem and the previous one, which generally cause difficulty in thin sectioning and breaks in sections, respectively, were embedded in the cylindrical molds full of epoxy resin. Locations of the three principal planes of wood anatomy could be determined in cylindrical resin-embedded microcores as follows: the transverse plane could be found on their side of cylinder, the radial one was vertical to the transverse, and the tangential ones were their circular ends of cylinder. The present embedding mold, therefore, can provide all three principal sections for microscopic wood anatomy from the side or ends of the same cylindrical microcore in principle. To confirm the usefulness of the resin-embedded microcores, we examined the differentiation of vessel elements during the period of earlywood formation on their transverse sections under microscopes, consequently could observe cell division in the cambial zone and sequential stages of vessel element differentiation, including cell expansion and deposition of the secondary cell wall. The present embedding mold for epoxy resin is simple but highly useful and innovative for a wide range of applications of microcores in microscopy for studies on tree-ring formation.     

Better epoxy resin embedding for electron microscopy at low relative humidity.

In the absence of other factors known to influence sectioning properties, high environmental relative humidity is shown to yield poorly embedded tissue. Humidity-related effects are avoided if the following embedding precedure is used; impregnate tissues using the following solutions 1) 70% alcohol - 5 minutes, 2) 95% alcohol - 2 x 15 minutes, 3) absolute alcohol - 3 x 20 minutes, 4) acetone - 2 x 15 minutes, 5) 1:1 mixture of acetone-epoxy resin (DDSA, 63.4 g; Araldite 502, 5.6 g; Epon 812, 39.4 g; DMP-30, 2.6 g) - 1 hour, 6) acetone-epoxy resin 1:3 - 1 hour, 7) epoxy resin - 1 hour; complete the preparation of blocks as follows 8) when tissues have been oriented in epoxy resin in flat embedding molds, place molds in one evacuated vacuum desiccator 10 cm above a 2 cm layer of Drierite for 24 hours at room temperature, 9) raise temperature to 60 C and maintain for 3 days to cure resin.     

A reliable epoxy resin mixture and its application in routine biological transmission electron microscopy

Although there are many papers in the literature on materials and procedures for the embedding of tissue for transmission electron microscopy (TEM), most recent publications have emphasized techniques for specialized applications. Although these may in many cases also be suitable for routine applications in addition to the specialized applications for which they were developed, this may not be clear from the literature. This paper describes the formulation and suggested procedures for the use of an epoxy resin mixture which has been routinely used by novice and experienced workers with success for a wide variety of biological TEM investigations in a multi-user multi-disciplinary EM facility. Results are given of the use of this embedding medium in the investigation of a variety of tissue types.     

Method of radioautographic study of cell cultures

The method of radioautographic study of cell cultures is suggested. It is based on culture embedding into epoxy resin in situ. After this manipulation the photolayer on the lower surface of the polymerized epoxy unit with the cell culture in it is applied. The advantages of this method are discussed.     

Differential staining of tannin in sections of epoxy-embedded plant cells.

A staining procedure is described for the light microscopic localization of ergastic tannins in epoxy sections of plant cells embedded for study by transmission electron microscopy. Callus and cell suspensions of Pseudotsuga menziesii and Pinus taeda fixed in glutaraldehyde:acrolein and then OsO4, followed by epoxy embedding, were sectioned 0.5 mum thick, stained on a glass slide with ethanolic Sudan black B at 60 C as described by Bronner, and then mounted in Karo syrup. Tannin deposits stained brownish-orange and were easily distinguished from lipid bodies of similar size, which stained dark blue to black, and from starch grains, which were unstained. The significance of this differential polychromasia was confirmed by transmission electron microscopy. This staining procedure should prove valuable in the cytoplasmic evaluation of the plant cell ergastics (especially tannins) via light microscopy whether or not electroc microscopic examination is intended.     

The ultrastructural localisation of cadmium.

A modified technique for the ultrastructural localisation of heavy metals is described in this paper. The method involves precipitation of heavy metals as sulphides in the tissue by using (NH4)2 S after brief fixation in glutaraldehyde. The sulphides are, in the presence of a physical developer, then used to catalyse the reduction of silver ions into visible molecular silver. This latter step of physical development has been normally carried out after embedding and sectioning. However, when we followed this method we found that the dark metal sulphide was lost from the tissue during the embedding in epoxy resin. Hence the method was unsuitable for our proposed experiment on the ultrastructural localisation of cadmium. We subsequently modified the technique primarily by treating very thin tissue slices with the developer before dehydration and embedding, thus eliminating any problem from sulphide loss. This modified technique was used to investigate the ultrastructural localisation of cadmium in the kidneys of mice which had been exposed to 50 ppm cadmium in their drinking water for up to eight months. The molecular silver was found to be located mainly in the proximal tubule cells, either as dense clumps in apical vesicles and lysosomes or diffuse grains throughout the cytoplasm of the cells particularly in the basal region. We interpret these results as indicating that cadmium is found in the apical vesicles, lysosomes and cytoplasm of proximal tubule cells.     

Better Epoxy Resin Embedding for Electron Microscopy at Low Relative Humidity

In the absence of other factors known to influence sectioning properties, high environmental relative humidity is shown to yield poorly embedded tissue. Humidity-related effects are avoided if the following embedding precedure is used: impregnate tissues using the following solutions 1) 70% alcohol—5 minutes, 2) 95% alcohol—4 × 15 minutes, 3) absolute alcohol—3 × 40 minutes, 4) acetone—2 × 15 minutes, 5) 1:1 mixture of acetone-epoxy resin (DDSA, 63.4 g; Araldite 502, 5.6 g; Epon 814,39.4 g; DMP-30, 2.6 g)— 1 hour, 6) acetone-epoxy resin 13—1 hour, 7) epoxy resin—1 hour: complete the preparation of blocks as follows 8) when tissues have been oriented in epoxy resin in flat embedding molds, place molds in one evacuated vacuum desiccator 10 cm above a 2 cm layer of Drierite for 24 hours at room temperature, 9) raise temperature to 60 C and maintain for 3 days to cure resin.     

Extraction of [14C] vitamin A from rat liver and kidney during processing for transmission electron microscopy.

The retention of radioisotope-labeled vitamin A during processing for electron microscopy was investigated using the livers and kidneys of vitamin A deficient rats. [15-14C]Retinol (3muCi/animal) was administered by esophageal intubation to male rats which had been maintained on a vitamin A deficient diet for five or six weeks postweaning. Glutaraldehyde- or osmium-fixed tissue was processed by three methods: a) routine (a graded series of ethanols, propylene oxide and epoxy), b) rapid (75% and 95% ethanol with three changes of epoxy), or c) water-soluble embedding (70% and 80% hydroxypropyl methacrylate). Water-soluble embedding retained the highest percentage of label in the tissue (liver: 96.31%; kidney: 98.68%). Inclusion of osmium tetroxide in the processing sequence and minimal exposure of tissue to lipid solvents were necessary for good retention of labeled vitamin A in tissues.     

Epoxy Resins in Electron Microscopy

A method of embedding biological specimens in araldite 502 (Ciba) has been developed for materials available in the United States. Araldite-embedded tissues are suitable for electron microscopy, but the cutting qualities of the resin necessitates more than routine attention during microtomy. The rather high viscosity of araldite 502 also seems to be an unnecessary handicap. The less viscous epoxy epon 812 (Shell) produces specimens with improved cutting qualities, and has several features—low shrinkage and absence of specimen damage during cure, minimal compression of sections, relative absence of electron beam-induced section damage, etc.—which recommends it as a routine embedding material. The hardness of the cured resin can be easily adjusted by several methods to suit the materials embedded in it. Several problems and advantages of working with sections of epoxy resins are also discussed.     

Electron Microscopic Study of a Slime Layer

Slime layers are being studied in our laboratories in an attempt to understand their functions in the control of pollution in natural streams. A method for fixing, staining, and embedding microorganisms in the intact slime has been developed. In this method, epoxy resin discs are placed in a holder and are introduced into a simulated stream. After various periods of time the discs are punched out of the holder into the fixative. The disc with the attached slime is fixed, stained (4% osmium tetroxide plus ruthenium red), dehydrated, and embedded in epoxy resin so that thin sections can be cut through the vertical plane of the slime mass. Such thin sections permit detailed examination of the attached layer, the surface-slime interface, the spatial relationships between cells in the vertical slime structure, and the strands of extracellular material between and around cells. No special attachment structures were noted as the cells appeared to be attached to the surface by extracellular material alone. This material was observed in strands and netlike forms between cells which are positioned 1 to 4 mum apart in the slime.     

N-VINYLPYRROLIDONE AS A WATER COMPATIBLE CONSTITUENT OF EMBEDDING RESINS FOR SECTIONING IN ELECTRON MICROSCOPY

The use as an embedding resin for ultrathin sectioning of a cross-linked triple copolymer of N-vinylpyrrolidone, acrylonitrile, and ethylene glycol dimethacrylate is described. The first of these components is miscible with water, in all proportions, and can be used as a dehydrating agent, or, alternatively, ethanol may be used in the standard way. Polymerization is carried out at 37°C or even lower temperatures. This resin is unsuitable for use after osmium fixatives, but after permanganates it gives results similar to epoxy. Photographs of rye root-tip cells fixed in permanganate and sectioned in this resin are presented. Because of the water-permeable nature of the product and low polymerization temperature, this resin appears to have possibilities for histochemistry.     

An Effective Method of Preparing Sections of Bacillus polymyxa Sporangia and Spores for Electron Microscopy

Bacillus polymyxa sporangia and spores were prepared for examination in the electron microscope by methods whose critical features were apparently: judicious use of vacuum, to encourage complete penetration of the embedding medium; the use of epoxy resins as embedding media; and cutting of the thin sections with a diamond knife. Electron micrographs of material prepared in this manner exhibit undeformed sporangial sections. Some of the structures revealed have been shown before, though perhaps less distinctly; other structures are revealed here for the first time. While this single study does not pretend to elucidate all the complexities of sporulation in bacteria, these and similar images should make this possible, and some mention of the preparatory techniques that lead to them seems advisable at this time.