Extraction of membrane lipids during fixation,dehydration and embedding of Acholeplasma laidlawii-cells for electron microscopy

The aim of the present investigation was to study the extent to which lipids are extracted from biological membranes during dehydration and embedding procedures carried out at high or low temperatures. Cells of Acholeplasma laidlawii were used as experimental material, since the lipids of this bacterium easily can be radioactively labelled without labelling the rest of the cell, and the lipids are almost entirely located in the cytoplasmic membrane. The cells were fixed at 277 K with glutaraldehyde, sequentially with this reagent and osmium tetroxide, or with glutaraldehyde, osmium tetroxide and uranyl acetate in that order. Loss of lipid during these procedures was negligible. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at room temperature and embedded in Epon at 333 K, i.e. subjected to a conventional treatment, about 90% of the lipid content of the cells was extracted. The loss was reduced to c. 20% when treatment with uranyl acetate was included in the procedure and the non-polar methacrylate resin Lowicryl HM20 was substituted for Epon. When cells fixed with glutaraldehyde and osmium tetroxide were dehydrated with ethanol at 238 K and embedded in Lowicryl HM20 at room temperature, practically no lipid was extracted. Substitution of the polar methacrylate-acrylate resin Lowicryl K4M for Lowicryl HM20 resulted in the loss of about half of the lipid content of the cells. The use of ethanediol as dehydrating agent instead of ethanol did not diminish the extraction. Cells fixed solely with glutaraldehyde lost about half of their lipid content, even when both dehydration and embedding was performed at 238 K. The lipid material extracted from glutaraldehyde-fixed cells contained slightly more saturated fatty acids than that remaining in the cells. The reverse was true for osmium tetroxide-fixed cells. With respect to lipid species, the extractions were generally rather unspecific.     

Static and dynamic experiments in cryo-electron microscopy: comparative observations using high-vacuum, low-voltage and low-vacuum SEM

We carried out a unique comparative study between three modes of cryo‐scanning electron imaging: high‐vacuum, low‐voltage and low‐vacuum, using ice cream as a model system. Specimens were investigated both with and without a conductive coating (Au/Pd) and at temperatures for which ice either remains fully frozen (< ?110 °C) or undergoes sublimation (?110 to ?90 °C). At high magnification, high‐vacuum imaging of coated specimens gave the best results for ‘static’ specimens (i.e. containing fully frozen ice). Low voltages, such as 1 kV, could be used for imaging uncoated specimens at high vacuum, although slight ‘classical’ charging artefacts remained an issue, and the reduced electron beam penetration tended to decrease the definition between different microstructural features. However, this mode was useful for observing in situ sublimation from uncoated specimens. Low‐vacuum mode, involving small partial pressures of nitrogen gas, was particularly suited to in situ sublimation work: when sublimation was carried out in low vacuum in the absence of an anti‐contaminator plate, sublimation rates were significantly reduced. This is attributed to a small partial pressure of sublimated water vapour remaining near the specimen surface, enhancing thermodynamic stability.     

Freeze-substitution without aldehyde or osmium fixatives: ultrastructure and implications for immunocytochemistry

Cryo-fixation followed by freeze-substitution without aldehyde or osmium fixation has been investigated as a method for preparing biological specimens with a view to minimizing antigenic alteration. Samples of both solid tissues (mouse small intestine and human kidney) and a human tumour cell line grown in vitro were rapidly frozen by impact (slammed) onto a copper block cooled with liquid nitrogen. They were freeze-substituted at ?80°C in methanol, and embedded at low temperature in Lowicryl K4M or HM20. Resin blocks were polymerized by ultraviolet light. Well-preserved ultrastructure was observed in the outer 10–15 μm of all samples. Positive immunocytochemical localization of fixation-resistant and fixation-labile antigens was obtained on sections of human kidney and the human breast tumour cell line ZR-75-1 at both light and electron microscope levels.     

Ultrastructural preservation of nuclei and chromatin: improvement with low-temperature methods

The ultrastructure of chromatin has been examined in nuclei prepared by a variety of low-temperature methods. Embedding glutaraldehyde (GA)-fixed nuclei in Lowicryl K4M or K11M following dehydration by the progressive lowering of temperature (PLT) method, or in K11M following spray freezing and freeze substitution (FS), produces chromatin fibres that have, in situ, a diameter close to the in vivo state, and show internal structural details consistent with patterns of nucleosome packing previously observed only in preparations of isolated fibres. This is a temperature-dependent effect; fibres conventionally dehydrated and embedded in Lowicryl at 0°C or in conventional epoxy resin at 60°C have lower and less uniform diameters, and lack internal structural details. Of the techniques used, spray freezing followed by FS resulted in the most notable improvement over conventional methods. Inclusion of GA during FS of rapidly frozen, unfixed nuclei in methanol does not result in cross-linking of nuclear proteins. In acetone, however, cross-linking by GA occurs at — 45°C, or at lower temperatures if the water content of the acetone-based FS media is kept deliberately high. Substitution regimes employing GA alone or in combination with uranyl acetate and/or osmium tetroxide do not result in fibre morphologies comparable to either prefixed or unfixed nuclei substituted in additive-free substitution media. Whole fibroblasts show excellent preservation of nuclei and the nuclear/cytoplasmic interface after spray freezing followed by FS and low-temperature embedding.     

Why low temperature embedding for X-ray microanalytical investigations?

Freeze-drying followed by infiltration with resin and polymerization by UV light at low temperatures and under constant vacuum conditions is an alternative tissue preparation technique for microprobe analysis. Embedding is carried out with the nonpolar low-temperature embedding resin (Lowicryl HM20) which allows infiltration and polymerization at temperatures down to ?50°C. Sections of low temperature embedded material can be cut dry at ?60°C or at room temperature. Sectioning at low temperatures is an alternative for preparations that are difficult to cut at room temperature. The morphological preservation is adequate for the identification of structures such as mitochondria, lysosomes and different types of endoplasmic reticulum in liver cells. Some physical properties of Lowicryl resins, such as mass loss under the electron beam and high contrast, are positive characteristics for the analysis of semi-thick sections. No significant differences in the elemental composition could be detected between tissue which was freeze-dried or freeze-substituted prior to embedding. Freeze-drying is less time consuming. By avoiding contact with organic solvents the risks of ion loss and redistribution are diminished. In contrast to freeze-dried thin cryosections, low temperature embedded material can be sectioned for light microscopy and areas of interest chosen for further thin sectioning. This is of great importance in work with tissues with complicated morphology and heterogeneous cell populations. The initial preparative step—the cryofixation— determines to a high degree the morphological preservation of freeze-dried and embedded tissue.     

Rapid freeze-substitution preserves membranes in high-pressure frozen tissue culture cells

We describe a method for high‐pressure freezing and rapid freeze‐substitution of cells in tissue culture which provides excellent preservation of membrane detail with negligible ice segregation artefacts. Cells grown on sapphire discs were placed ‘face to face’ without removal of tissue culture medium and frozen without the protection of aluminium planchettes. This reduction in thermal load of the sample/holder combination resulted in freezing of cells without visible ice‐crystal artefact. Freeze‐substitution at −90°C for 60 min in acetone containing 2% uranyl acetate, followed by warming to −50°C and embedding in Lowicryl HM20 gave consistent and clear membrane detail even when imaged without section contrasting. Preliminary data indicates that the high intrinsic contrast of samples prepared in this way will be valuable for tomographic studies. Immunolabelling sensitivity of sections of samples prepared by this rapid substitution technique was poor; however, reducing the uranyl acetate concentration in the substitution medium to 0.2% resulted in improved labelling. Samples substituted in this lower concentration of uranyl acetate also gave good membrane detail when imaged after section contrasting.     

Freeze-substitution: a method for the rapid arrest and chemical fixation of spermatozoa

A procedure for the freeze-substitution fixation of spermatozoa has been developed. Physical fixation of the motile cells is effected very rapidly by immersing the sperm in Freon-22 at ?146°C. Chemical fixation, with glutaraldehyde, is then imposed on the immobilized sperm after substitution of the ice matrix at ?50°C. The substitution is achieved with the solvent ethylene glycol in the manner described by Pease (1967). (Subsidiary experiments confirm that substitution of ice does occur at ?50°C and that chemical fixation by glutaraldehyde occurs at temperatures at least as low as ?20°C.) The spermatozoa are then embedded in Epon and examined as thin sections. Other techniques—substitution in acetone containing osmium tetroxide, the inclusion of formaldehyde with ethylene glycol as a chemical fixative, and the inclusion of agar in the diluent used to suspend the spermatozoa—have been tried but were unsatisfactory. Freezing stops the movement very rapidly and, as little subsequent disturbance occurs, it should be possible to preserve transient changes in the fine structure of the flagellum which might be related to a mechanism for the generation of bends. The observations in this paper are confined to the behaviour of the proximal part of the midpiece of the rat spermatozoon. It is demonstrated that bending of this part of the flagellum is restricted, to a remarkable degree, to one plane, the plane in which the sperm nucleus is flattened. This plane is almost exactly perpendicular to the plane containing the two central tubules of the axoneme. It has been confirmed that the axonemal complex has a straight course through the midpiece during those beats of the flagellum which are not accompanied by rotation of the entire cell. Lastly, it appears that the nine dense fibres do not undergo transient displacements as the flagellum bends.     

High-pressure freezing for immunocytochemistry

Ultrastructural immunocytochemistry requires that minimal damage to antigens is imposed by the processing methods. Immersion fixation in cross-linking fixatives with their potential to damage antigens is not an ideal approach and rapid freezing as an alternative sample-stabilization step has a number of advantages. Rapid freezing at ambient pressure restricts the thickness of well-frozen material obtainable to ≈ 15 μm or less. In contrast, high-pressure freezing has been demonstrated to provide ice-crystal-artefact-free freezing of samples up to 200 μm in thickness. There have been few reports of high-pressure freezing for immunocytochemical studies and there is no consensus on the choice of post-freezing sample preparation. A range of freeze-substitution time and temperature protocols were compared with improved tissue architecture as the primary goal, but also to compare ease of resin-embedding, polymerization and immunocytochemical labelling. Freeze-substitution in acetone containing 2% osmium tetroxide followed by epoxy-resin embedding at room temperature gave optimum morphology. Freeze-substitution in methanol was completed within 18 h and in tetrahydrofuran within 48 h but the cellular morphology of the Lowicryl-embedded samples was not as good as when samples were substituted in pure acetone. Acetone freeze-substitution was slow, taking at least 6 days to complete, and gave blocks which were difficult to embed in Lowicryl HM20. Careful handling of frozen samples avoiding rapid temperature changes reduced apparent ice-crystal damage in sections of embedded material. Thus a slow warm-up to freeze-substitution temperature and a long substitution time in acetone gave the best results in terms of freezing quality and cellular morphology. No clear differences emerged between the different freeze-substitution media from immunocytochemical labelling experiments.     

Effect of processing methods for transmission electron microscopy on corneal collagen fibrils diameter and spacing

Introduction: The corneal tissue was processed in fixatives and embedded in resin for transmission electron microscopy to observe the ultrastructure of the collagen fibrils (CFs). The effect of these processing methods on the CF diameter and the interfibrillar spacing was studied. Methods: Four normal human corneal buttons were used for this study. A part of each cornea was fixed in 2.5% glutaraldehyde containing cuprolinic blue in sodium acetate buffer and embedded in spurr's resin (SpurrCB). A second part of each cornea was fixed in 2.5% glutaraldehyde + osmium tetroxide and embedded spurr's resin (SpurrOsm). The third part of each cornea was fixed in paraformaldehyde (4%) and embedded in LR White at 4°C (LRWhite). Ultrathin sections were stained with uranyl acetate and lead citrate. Results: In the tissue, fixed in SpurrCB, the diameter was 38.4 ± 5.9 nm and spacing between CF was 52.5 ± 5.3 nm. In the tissue fixed in SpurrOsm, the diameter was 28.37 ± 5.84 nm and spacing between CF was 45 ± 4.57 nm. In the tissue fixed in LR White, the CF diameter was 24 ± 2.3 nm and spacing between CF was 39.0 ± 4.2 nm. The diameters and interfibrillar spacing of the tissue processed by SpurrCB, SpurrOsm, and LRWhite were significantly different (P < 0.001) from one another. Conclusion: Our study shows that there is a variation in the CF diameter and spacing depending on the method of fixation and embedding resins used. This needs to be considered when comparative studies using different methods are done. Microsc. Res. Tech. 2012. © 2012 Wiley Periodicals, Inc.     

Direct visualization of receptor arrays in frozen-hydrated sections and plunge-frozen specimens of E. coli engineered to overproduce the chemotaxis receptor Tsr

We have recently reported electron tomographic studies of sections obtained from chemically fixed E. coli cells overproducing the 60‐kDa chemotaxis receptor Tsr. Membrane extracts from these cells prepared in the presence of Tween‐80 display hexagonally close‐packed microcrystalline assemblies of Tsr, with a repeating unit large enough to accommodate six Tsr molecules arranged as trimers of receptor dimers. Here, we report the direct visualization of the Tsr receptor clusters in (i) vitrified cell suspensions of cells overproducing Tsr, prepared by rapid plunge‐freezing, and (ii) frozen‐hydrated sections obtained from cells frozen under high pressure. The frozen‐hydrated sections were generated by sectioning at ?150 °C using a diamond knife with a 25° knife angle, with nominal thicknesses ranging from 20 to 60 nm. There is excellent correspondence between the spatial arrangement of receptors in thin frozen‐hydrated sections and the arrangements found in negatively stained membrane extracts and plunge‐frozen cells, highlighting the potential of using frozen‐hydrated sections for the study of macromolecular assemblies within cells under near‐native conditions.     

A synchrotron X-ray study of the changes occurring in the corneal stroma during processing for electron microscopy

Using a high-intensity synchrotron X-ray source, the structural changes occurring in the corneal stroma were monitored during each stage of several different processing runs for the transmission electron microscope (TEM) and scanning electron microscope (SEM). The parameters studied were interfibrillar spacing, intermolecular spacing, D-periodicity and fibril diameter. The processing schedule that produced the least changes in spacings for TEM specimens involved extended fixation in glutaraldehyde followed by low-temperature embedding in Lowicryl K4M resin. However, interfibrillar material was better preserved after embedding in LR White resin or Nanoplast. Almost every processing stage for electron microscopy produced significant changes in one or more structural parameters in the cornea. Glutaraldehyde fixation significantly increased the intermolecular spacings, while resin infiltration and resin polymerization each resulted in shrinkage of all the spacings monitored. Critical-point drying for SEM specimens resulted in considerable shrinkage in all three spacings, but was still preferable to air drying, which caused reduction in the order of the fibril packing, resulting in loss of the interfibrillar X-ray pattern. Perhaps the most drastic effect was caused by post-fixation in osmium tetroxide, which resulted in loss of the intermolecular pattern, and also increased the amount of shrinkage in the interfibrillar spacings and the D-periodicity which occurred during later stages of processing.     

The effect of an Ni–Cr protective layer on cyclic oxidation of Ti3Al

The effect of an 80Ni?20Cr (at.%) metallic coating on the cyclic oxidation behaviour of a Ti₃Al‐based alloy with the composition Ti?25Al?11Nb (at.%) was investigated in this study. Cyclic oxidation tests were carried out in air at 600 °C and 900 °C for 120 h. For one cycle test, the specimens were held for 24 h at test temperature and then furnace‐cooled to room temperature. The oxidation rate was determined by plotting the mass gain per unit surface area of the specimen vs. exposure time. The morphology and composition of the oxidation products were characterized on the cross‐section of the specimens by scanning electron microscopy, energy‐dispersive X‐ray spectroscopy and atomic force microscopy. The oxidation scale forms during exposure at both 600 °C and 900 °C. TiO₂ is the main oxide component, whereas the Al₂O₃ layer appears only discontinuously. The remarkable improvement in oxidation resistance at 900 °C was attributed to the chemical composition and structure of the scale formed on the 80Ni?20Cr coating.     

Optimal preparatory procedures of cryofixation for immunocytochemistry

To examine the optimal preparatory procedures of cryofixation for immunocytochemistry, the labeling density over the antigenic sites in cells processed by various protocols of freeze-substitution and embedding was quantitatively evaluated. Fresh tissue blocks of gerbil parotid gland were quickly frozen by a metal contact method using liquid helium and freezesubstituted with one of the following media: 4% OsO₄ in acetone or 0.4% OsO₄ in acetone or 0.3% glutaraldehyde in acetone. They were then embedded in either an Epon-Araldite mixture or Araldite 6005, which were polymerized at 60°C and 50°C, respectively. Some frozen samples substituted with aldehyde-containing acetone were embedded in Lowicryl K4M (polymerized at —30°C). Immunocytochemical localization of amylase was examined by indirect immunostaining by using antigerbil parotid amylase antibody and protein A/gold complex. Thin sections of epoxyresin-embedded materials were treated with oxidizing agents before immunostaining. The central dense core of heterogeneous secretory granules in the acinar cells was heavily labeled with immunogold, regardless of substitution media and embedding resins employed. The labeling density on thin sections of all the cryofixed materials examined was about 1.5 times or more as high as in those processed by conventional chemical fixation. The highest value of the labeling density was obtained from material which was substituted with 0.3% glutaraldehyde in acetone and embedded in Araldite 6005. Substitution with osmium-containing acetone appeared not to seriously affect immunoreactivity of the antigenic sites and was advantageous because of the distinctive images of membranes. Advantages and disadvantages of the individual protocols employed are discussed.     

The axonal transmission of Herpes simplex virus to epidermal cells: a novel use of the freeze substitution technique applied to explant cultures retained on cover slips

Retaining the ultrastructural arrangement of a mixed-cell culture on a solid support while processing for immunocytochemical study is a technical challenge. We developed a technique to study the axonal transport of the Herpes simplex virus from dorsal root ganglia sensory neurones to epidermal cells. Autologous explants of human foetal dorsal root ganglia and skin were cultured on plastic cover slips. Axon fascicles grew from the ganglia to the epidermal cells and the ganglia were inoculated selectively with virus. The whole preparation, retained on the cover slip, was fixed with formaldehyde 4% (freshly prepared from paraformaldehyde)/glutaraldehyde 0.1%, processed by freeze substitution, and embedded in Lowicryl HM20 resin. The edges of the cover slip in the block were trimmed, allowing clean and complete separation from the resin block, which retained the tissue. The resin block was placed in fresh HM20 and repolymerized. The polymerizing resin bonded strongly to the existing block. After trimming, serial sections were easily obtained and successfully immunolabelled for viral proteins. This is a convenient technique for immunolabelling tissue grown on cover slips in which the preservation of the ultrastructural interactions between different cells is important. It should be adaptable to a number of cell-culture applications and has a number of advantages over other techniques.     

Developments of new Lowicryl® resins for embedding biological specimens at even lower temperatures

Two new Lowicryl resins have been developed for embedding biological materials at temperatures down to 210K (hydrophilic K11M) and to 190K (hydrophobic HM23). They have similar properties to Lowicryl K4M and HM20. The new resins were first tested for low temperature applications by the ‘progressive lowering of temperature’ procedure and this shows that the low viscosity of K11M and HM23 is favourable for the infiltration of biological specimens. Hardening is achieved through photo-polymerization at these lower temperatures. These properties make K11M and HM23 suitable for cryosubstitution of rapidly frozen material and it is speculated that the preservation of antigenicity may be further improved.     

The effect of six fixatives on the areas of rabbit neurons and rabbit and rat cerebral slices.

Cell bodies of cerebral neurons from rabbits were isolated by hand, transferred to a microscope slide in a ‘199’ medium, and the projected areas of their cytoplasm and nuclei were measured. In sixty-four cells there was a strong correlation between the projected areas of the cytoplasm and the nuclei (r=0.66, P < 0001), and the ratio of the projected areas was 11.6. The medium was then replaced by the following fixatives: formalin (10% v/v), Bouin's, Carnoy's, Susas, glutaraldehyde (5% v/v), and osmium tetroxide (1% w/v). Cerebral slices were obtained from the grey and white matter of rabbit and rat, and were also measured before and after treatment with similar fixatives. Relative to the unfixed areas, glutaraldehyde and osmium tetroxide had no significant effect on the projected areas of isolated cells, Carnoy's fixative shrunk the areas of the cytoplasm by means of 16.26%, Bouin's by a mean of 49%, and Susas by a mean of 65%. The shrinkage of the cytoplasm and the nuclei was not significantly different from that of the nuclei for each of these three fixatives individually, but with formalin the mean shrinkage of the cytoplasm was 46% while the nuclei did not shrink significantly. Using the same fixatives the effect on the areas of the cerebral slides from rabbit and rat were as follows: glutaraldehyde and osmium tetroxide caused no change in area; Carnoy's, formalin and Bouin's fixative diminished the areas by a mean of 10–20%, and Susa's by a mean of 35%. It was concluded that a particular fixative often caused a different degree of shrinkage to the cytoplasm, nuclei and cerebral slice. In general, the lower the osmotic pressure of the fixative, the less shrinkage it induced.     

Enzyme-gold affinity labelling of cellulose

The enzyme-linked colloidal gold affinity labelling technique was tested as a method to localize cellulose on thin sections of plant cell walls and slime mold spores. Commercially available cellulase from cultures of Trichoderma reesei, the main components being cellobiohydrolase I and II (CBH I, CBH II) and endoglucanase (EG), was linked to colloidal gold by using standard techniques and applied as a dilute, buffered suspension to thin sections. After brief exposure, e.g., 15–30 minutes, cellulose exposed on the surface of sections was labelled with the enzyme-gold complex. Poststaining did not appear to have a deleterious effect on the labelled sections. The specificity of labelling was demonstrated by its complete inhibition when carboxymethylcellulose was incorporated in the labelling mixture, by lack of labelling of 1,4-β-mannans or 1,3-β-xylans in noncellulosic walls of marine algae, by lack of labelling of 1,4-β-glucans in chitin, by much lower labelling density when done at 4°C, and by lack of labelling when sections were predigested with cellulase. Labelling with the crude commercial cellulase was compared to labelling with purified CBH I-, CBH II-, and EG-linked colloidal gold, and the labelling pattern was similar. This method was found useful on conventionally fixed material and required no special preparation other than the use of inert (Ni or Au) grids and 0.5% gelatin to reduce nonspecific binding of the gold complex. Labelling was similar in the several embedding resins tested: LR White, Lowicryl K4M, Epon 812, and Spurr's. The cellulase-gold probe remained active for at least 4 weeks at 4°C and much longer when frozen at ?80°C in 20% glycerol. This technique should prove useful in studies of cellulose degradation and cellulose deposition and of the interaction of cellulose with other wall components.     

A method for preparing quick-frozen,freeze-substituted cells for transmission electron microscopy and immunocytochemistry

A quick-freeze, freeze-substitution method is described which employs glutaraldehyde as well as osmium tetroxide (OsO₄) in a ‘double-fixation’ protocol comparable to that used for conventional transmission electron microscopy. Cultured cells are quick-frozen in Freon 22 and freeze-substituted in an ethanolic solution of glutaraldehyde. Specimens destined for TEM are postfixed in OsO₄ in acetone, embedded in Epon-Araldite, and sectioned. This method yielded ultrastructural preservation which was comparable to that obtained from methods employing OsO₄ alone as a freeze-substitution fixative. However, if glutaraldehyde is used alone as a freeze-substitution fixative, specimens can be processed for immunocytochemistry without additional treatment with permeabilizing agents.     

Human teeth biobank: Microbiological analysis of the teeth storage solution

The cross‐infections may occur during handling of dental elements, affecting the health of dental practitioners and researchers. This study aimed to analyze the influence of the storage medium temperature on the bacterial contingent of the human teeth used for research purposes. Thirty human teeth were donated to the Human Teeth Biobank immediately after extraction. The teeth were cleaned with tap water and neutral soap. The teeth were randomly distributed according to the temperature of the storage solution (deionized water): at 4 °C (refrigerator) or at ?10 °C (freezer) and were stored individually in sterile vials during 60 days. After this period, a microbiological analysis (CFU/mL) of the storage solutions was performed and teeth were submitted to SEM analysis. Data were analyzed by Kruskal–Wallis test followed by Dunn's post‐test (p ≤ .05). Total aerobic bacteria ranged from 5.8 to 8.4 log₁₀ CFU/mL for refrigerated solution and from 1.9 to 8.5 log₁₀ CFU/mL for frozen solution. No statistical differences were found between the storage solutions (p > .05). The counts of Streptococcus spp., Lactobacillus spp., and Staphylococcus spp. were similar for both storage solutions (p > .05). SEM analysis showed spiral‐ and rod‐shaped bacteria attached on teeth stored under 4 °C, which may suggest the presence of Treponema spp. and Lactobacillus spp. Similar morphological forms were found on teeth stored under ?10 °C. A biofilm organized in honeycomb‐like form was found in the frozen teeth. Cocci were eventually found in all the samples. It was concluded that bacterial growth and survival were not influenced by the temperature of the teeth storage solution.     

Improved sectioning and ultrastructure of bacteria and animal cells embedded in lowicryl

Lowicryl K4M-embedded Gram-positive and Gram-negative bacteria have a tendency to separate between the cell surface and the resin. This often leads to distortion of bacteria and more especially of mycobacteria. We describe attempts made to overcome this technical problem. Different assays were made on Bacillus subtilis, Escherichia coli, and Mycobacterium avium: (1) Modification of the bacterial surface by coating of bacteria with proteinic compounds; (2) treatment of bacteria with metallic salts known to modify cell wall polysaccharides; and (3) comparison between Lowicryl K4M and HM20. Conditions have been found in which the separation of all bacterial species from the resin is abolished. The most important factor appeared to be the treatment of bacteria before dehydration, with 0.5% uranyl acetate for 30 min. The second most important factor, especially for M. avium and to a lower extent for Gram-negative bacteria, was the use of Lowicryl HM20. Pre-embedding in gelatin instead of agar improved sectioning of M. avium, but had no effects on the other bacterial species. These conditions applied to macrophages infected with Shigella dysenteriae or M. avium also gave excellent results. In addition to sectioning improvement of bacteria, uranyl acetate improved the ultrastructure of bacteria and macrophages. All organelles were more clearly delineated and, hence, more easily identified. Finally, it was shown that UA treatment did not affect immunogold labeling of a variety of antigens.