Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

The Use of Dimethylsulfoxide for Fixation of Yeasts for Electron Microscopy

Conventional methods of chemical fixation are often inadequate for preserving yeast ultrastructure. The thick cell wall severely limits penetration of fixatives rendering poor detail of the cell wall, membranes, and overall anatomy. Dimethylsulfoxide (DMSO) enhances penetration of chemicals and has been added to fixatives to improve cell preservation. At high concentrations (5 to 50%), however, it affects ultrastructure unpredictably. We found that adding 0.1% DMSO to fixatives greatly improved retention of yeast ultrastructure. Candida albicans, C. glabrata and Aspergillusfumigatus were fixed for 3 hr in 3% paraformaldehyde, 1% glutaraldehyde, 1 mil MgCl₂, 1 mM CaCl₂, 0.1% DMSO in 0.1 M sodium cacodylate buffer followed by 1% OsO₄, 1% K₂Cr₂O₇, 0.85% NaCl. 0.1% DMSO in the same buffer. Thin epoxy sections were post-stained in uranyl acetate and lead citrate. The multilayered character of the cell wall was distinct and well structured. Addition of ruthenium red or alcian blue to the fixatives further enhanced the outer fibrillar layer. The plasma membrane was contiguous and tightly adjacent to the inner manno-protein layer of the cell wall. The cytoplasm was well preserved and the overall preservation of the yeast ultrastructure was significantly improved.     

Immunoelectron microscopic studies of the ultrastructure of myosin filaments in Dictyostelium discoideum

We have examined the characteristics of myosin in situ in Dictyostelium amoebae. By an improved immunofluorescence method, we previously found rod-like structures that contain myosin, which we call "myosin rods", in amoebae (Yumura. S., and Fukui, Y. (1985) Nature, 314: 194-196). Although we prepared samples for electron microscopy using conventional chemical fixation to clarify the ultrastructure of the myosin rods, we could not find any filamentous structures similar to myosin thick filaments. Therefore, we examined the effects of chemical fixatives on the myosin rods in situ by immunofluorescence staining. When cells were fixed in more than 0.05% glutaraldehyde or more than 1% osmium tetroxide at 4 degrees C, the myosin rods disappeared. These effects did not result from loss of the antigenicity, because a monoclonal myosin-specific antibody was able to react with synthetic myosin filaments treated with 0.5% glutaraldehyde or 2% osmium tetroxide. Cells fixed by the procedure used for immunofluorescence staining were post-fixed with permissible concentrations of chemical fixatives and prepared for examination by transmission electron microscopy. We found discrete filaments of about 12 nm thickness between the microfilaments. These filaments were shown to contain myosin by immunoelectron microscopy with an immunogold probe. These filaments were thinner than synthetic myosin thick filaments formed in vitro in the presence of 10 mM MgCl2, but they were similar to those formed in the presence of 2 mM MgCl2, or under nearly physiological ionic conditions. The images after immunofluorescence and immunogold labeling both suggested that these 12-nm-thick filaments in Dictyostelium amoebae were myosin filaments in situ.     

Quantitative seasonal variation in mitochondrial ultrastructure of mesophyll cells ofDiapensia lapponica L. with reference to some effects of fixative osmolality

Summary Seasonal changes in the mitochondrial ultrastructure were examined in palisade parenchyma cells of a tuft-formingDiapensia lapponica L. collected at monthly intervals in Northern Finland. Quantitative analyses to measure volume and surface densities were conducted during different periods of growth (stages of growth, acclimation, winter period and deacclimation) in the annual cycle.The volume density was highest in the summer and lowest in the spring; the difference was significant with both fixatives used GA and GA/FA. The largest membrane area (the mitochondrial outer membrane and the cristal membranes together) was observed in the summer and autumn, and was significantly less in the winter and spring. This correlated with fewer mitochondria in the spring and a smaller number of cristae in the winter and spring. In the material fixed in GA/FA the distribution of length/width ratios of mitochondria was relatively uniform in all seasons. However, the mitochondrial ultrastructure had the most varied appearance during the winter. Hypertonie GA/FA solution did not cause significant differences either in the ultrastructure or the volume and surface densities of the mitochondria.Abbreviations GA glutaraldehyde - GA/FA glutaraldehyde/formaldehyde     

Possibility of the long-term fixation of the cells of a HeLa culture without disturbing their ultrastructure

It is shown that the composition of fixatives (2.5% glutaraldehyde in 0.1 M phosphate buffer with pH 7.2-7.4, and the mixture of 2.5% glutaraldehyde with 2% paraformaldehyde in 0.1 M phosphate buffer with pH 7.2-74) and duration of fixation (30 minutes, 24 hours, 7 days, and 30 days) under the room temperature exerts no influence on preservation of HeLa cultured cells. The ultrastructure of all the organelles of these cells is similar in any cases examined. All the membrane structures are well preserved; no condensation of chromatin is observed; the widths of the canals of endoplasmic reticulum, and of the intracristal and lateral spaces of mitochondria are invariable. Polysomes are present in the cytoplasm throughout the period of fixation.     

Ultrastructural study of the glomerular slit diaphragm in fresh unfixed kidneys by a quick-freezing method.

In normal kidneys fixed by perfusion with tannic acid and glutaraldehyde, glomerular slit diaphragms have been reported to consist of highly ordered and isoporous substructures with a zipper-like configuration. We have re-evaluated the ultrastructure of fixed or unfixed glomeruli using quick-freezing and deep-etching (QF-DE) and freeze-substitution (QF-FS) methods. In the fixed slit diaphragms, zipper-like substructures were often observed by the QF-DE method. In contrast, in fresh unfixed glomeruli the slit diaphragms mainly consisted of non-porous substructures. The slit diaphragms were more widely opened in the fixed glomeruli, as examined by the QF-FS method. These results suggest that the foot processes shrink during tissue preparation by conventional methods with chemical fixatives, and that the broadening of slit diaphragms and zipper-like substructures are formed by the pulling apart of adjacent foot processes due to shrinkage.     

Staining of interphase nuclei and mitotic figures in cultured cells with alcian blue 8GX

Cultured endothelial cells derived from bovine calf pulmonary artery were subjected to a variety of fixatives and stained with 1% Alcian blue 8GX at pH 2.59 to 3.26. Within this range of pH, interphase nuclei and especially mitotic figures were (a) strongly stained in cells fixed with 10% formalin (phosphate buffered or unbuffered) or 2.5% buffered glutaraldehyde, (b) weakly stained or unstained in cells fixed in formaldehyde containing divalent cations, and (c) unstained in cells fixed in acetic acid-containing fluids. However, optimal nuclear staining with Alcian blue under the conditions of this study was judged to be achieved after fixation with neutral phosphate buffered 10% formalin. Endothelial cell cytoplasm exhibited a similar fixative-dependent staining. At pH 2.59 the cytoplasm of interphase cells fixed in formaldehyde (containing no divalent cations) or glutaraldehyde remained unstained; however, at higher pH cytoplasmic staining did occur and it increased as pH increased. In contrast, when these latter fixatives were employed the cytoplasm of mitotic cells stained at all pH levels tested. In cultured endothelial cells after appropriate fixation, 1% Alcian blue 8GX (pH 2.59) was found to possess the ability to stain nuclei with a selectivity and intensity that compared favorably to those of the Feulgen reaction of Heidenhain iron hematoxylin but without the latters' length and complexity. Therefore, this procedure may provide a rapid, simple, and selective method for visualizing interphase nuclei or mitotic figures, or both in the majority of cultured cells.     

Staining of interphase nuclei and mitotic figures in cultured cells with Alcian blue 8GX

Summary Cultured endothelial cells derived from bovine calf pulmonary artery were subjected to a variety of fixatives and stained with 1% Alcian blue 8GX at pH 2.59 to 3.26. Within this range of pH, interphase nuclei and especially mitotic figures were (a) strongly stained in cells fixed with 10% formalin (phosphate buffered or unbuffered) or 2.5% buffered glutaraldehyde, (b) weakly stained or unstained in cells fixed in formaldehyde containing divalent cations, and (c) unstained in cells fixed in acetic acid-containing fluids. However, optimal nuclear staining with Alcian blue under the conditions of this study was judged to be achieved after fixation with neutral phosphate buffered 10% formalin. Endothelial cell cytoplasm exhibited a similar fixative-dependent staining. At pH 2.59 the cytoplasm of interphase cells fixed in formaldehyde (containing no divalent cations) or glutaraldehyde remained unstained; however, at higher pH cytoplasmic staining did occur and it increased as pH increased. In contrast, when these latter fixatives were employed the cytoplasm of mitotic cells stained at all pH levels tested. In cultured endothelial cells after appropriate fixation, 1% Alcian blue 8GX (pH 2.59) was found to possess the ability to stain nuclei with a selectivity and intensity that compared favorably to those of the Feulgen reaction or Heidenhain iron hematoxylin but without the latters’ length and complexity. Therefore, this procedure may provide a rapid, simple, and selective method for visualizing interphase nuclei or mitotic figures, or both in the majority of cultured cells.     

戊二醛浓度对免疫电镜胶体金标记密度影响的定量分析

 经4％多聚甲醛+0或0.5％戊二醛固定(1小时)大豆子叶细胞,大部分细胞器和蛋白体发生较大程度的变形,甚至解体。随着固定剂中戊二醛浓度升高至1.5、2.5％,细胞超微结构保存效果提高,蛋白体内反映7S蛋白质存在的胶体金颗粒密度分别为19.7和11.4个／µm2。     

Immunoelectron microscopic study of the insoluble antigens of bone marrow cells in rats

An immunoperoxidase study of the localization of insoluble antigens was carried out on the rat bone marrow cells. The effect of different fixatives and inhibitors of endogenous peroxidase on the cell ultrastructure and the preservation of immunoreactivity of the cell antigens. The best results were obtained while fixing with 1% paraformaldehyde and 0.05% glutaraldehyde mixture added with 0.5 saponin and using 10% acetic acid as an inhibitor of endogenous peroxidase. Differences were found in the localization of antigens and the intensity of immunoperoxidase staining in cells of different lines of differentiation and degree of maturity.     

Detection of hepatopancreatic parvovirus (HPV) of penaeid shrimp by in situ hybridization at the electron microscope level

A post-embedding in situ hybridization procedure was developed to detect hepatopancreatic parvovirus (HPV) of penaeid shrimp at the ultrastructural level. The procedure was optimized using sections of resin-embedded hepatopancreas from HPV-infected juvenile Penaeus monodon and postlarval P. chinensis. The hepatopancreata were fixed using various fixatives, dehydrated, and embedded in the hydrophilic resin Unicryl. A 592 bp HPV-specific DNA probe, labeled with DIG-11-dUTP, was tested both on semi-thin and ultra-thin sections and examined by light and electron microscopy, respectively. Hybridized probe was detected by means of an anti-DIG antibody conjugated to 10 nm gold particles and subsequent silver enhancement. Hybridization signal intensities were similar with all fixatives tested, but ultrastructure was best preserved with either 2 or 6% glutaraldehyde. Post-fixation with 1% osmium tetroxide improved ultrastructure but markedly decreased hybridization signal and induced non-specific deposition of gold and silver. Under optimized conditions, this technique was used to successfully follow the development of HPV from absorption and transport through the cytoplansm to nuclear penetration, replication and release by cytolysis. The probe signal was consistently observed among necrotic cell debris within the lumen of hepatopancreatic tubules, within the microvillous border of tubule epithelial cells, within the cytoplasm, and within diagnostic HPV intranuclear inclusion bodies. The nucleolus and karyoplasm of patently infected cells (i.e., showing HPV intranuclear inclusion bodies) were almost devoid of signal. Electron-lucent structures, known as intranuclear bodies, commonly found within the virogenic stroma, showed only weak labeling. This is the first use of in situ hybridization to detect HPV nucleic acids with the electron microscope. The technique should be useful for studying the pathogenesis of HPV.     

Development of a new primary fixative for electron microscopic immunocytochemical localization of intracellular antigens in cultured cells.

We have developed a new primary fixative that permits the localization of intracellular antigens with well preserved ultrastructural morphology. This primary fixation method employs a mixture of a water soluble carbodiimide with glutaraldehyde, and preserves morphology, yet produces a permeable cytosol matrix so that antibodies can gain access to fixed proteins. Cultured cells were primarily fixed, treated with detergent to permeabilize their membranes, reacted with peroxidase labeled antibodies, secondarily fixed, and embedded in situ. The variations in morphology and accessibility of intracellular antigens were evaluated for a variety of fixatives. Concanavalin A and alpha 2 macroglobulin were chosen as examples of intracellular protein antigens to evaluate these fixation methods. Both of the proteins were localized in intracellular vesicles.     

Use of Peroxidatic-Enzyme Staining to Enhance Resolution of Cultured Mammalian Cells Under Phase Microscopy

Staining of glutaraldehyde-fixed mammalian cells with peroxidatic enzymes (horseradish peroxidase or horse heart cytochrome c) greatly enhances resolution of their structure under phase microscopy. The topography of cell processes and regions of intercellular contact and overlapping is resolved precisely, even in dense cultures mounted in media which ordinarily do not permit clear demonstration of these areas. The technique is therefore a useful aid to the study of cultured cells with phase optics. Labeling depends on introducing free aldehydes into cells through the use of bi functional fixatives such as glutaraldehyde. Acetone or formaldehyde fixation prevents staining, and labeling intensity is greatly diminished by pretreatment with spermine, a polyamine that reacts with glutaraldehyde. Electron microscopy reveals that peroxidase tags membranes preferentially; some areas are labeled smoothly, others in a punctate manner. Ribosomes are sharply contrasted, but nuclei remain unstained. Cytochrome c labels condensed nuclear chromatin intensely, and also stains ribosomes and portions of the cyto plamic ground substance; membranes are mostly unmarked.     

Use of peroxidatic-enzyme staining to enhance resolution of cultured mammalian cells under phase microscopy.

Staining of glutaraldehyde-fixed mammalian cells with peroxidatic enzymes (horseradish peroxidase or horse heart cytochrome c) greatly enhances resolution of their structure under phase microscopy. The topography of cell processes and regions of intercellular contact and overlapping is resolved precisely, even in dense cultures mounted in media which ordinarily do not permit clear demonstration of these areas. The technique is therefore a useful aid to the study of cultured cells with phase optics. Labeling depends on introducing free aldehydes into cells through the use of bifunctional fixatives such as glutaraldehyde. Acetone or formaldehyde fixation prevents staining, and labeling intensity is greatly diminished by pretreatment with spermine, a polyamine that reacts with glutaraldehyde. Electron microscopy reveals that peroxidase tags membranes preferentially; some areas are labeled smoothly, others in a punctate manner. Ribosomes are sharply contrasted, but nuclei remain unstained. Cytochrome c labels condensed nuclear chromatin intensely, and also stains ribosomes and portions of the cytoplasmic ground substance; membranes are mostly unmarked.     

Osmolarity of osmium tetroxide and glutaraldehyde fixatives

Synopsis The evidence available to date for the importance of fixative osmolarity is considered together with some observations on the volume changes of crab axons after fixation by osmium tetroxide and glutaraldehyde. The results obtained are compared with those obtained from crab axons and from amphioxus skin cells which had been processed and examined with the electron microscope after initial fixation in fixatives of different composition. It is concluded that the osmolarity of the fixative vehicle is of considerable importance when the fixing agent is glutaraldehyde but is of less importance when the fixing agent is osmium tetroxide or a mixture of the two agents.Preliminary observations upon crab axons fixed with glutaraldehyde in a vehicle approximating to the internal composition of the cells suggest that this approach to the design of fixative vehicles may be useful.     

Effects of Fixation on Cell Volume of Marine Planktonic Protozoa

The effects of fixation on the cell volume of marine heterotrophic nanoflagellates and planktonic ciliates were investigated. Decreases in cell volume depended on the combination of the protozoan taxa and the particular fixative. For a particular fixative and protozoan species, degree of shrinkage was independent of physiological state. The volume of fixed cells was found to be approximately 20 to 55% lower than the cell volume of live organisms. For the heterotrophic microflagellates, the fixatives ranked, in order of decreasing effect on cell volume, as glutaraldehyde, formaldehyde, acid Lugol's solution, and modified van der Veer solution. With oligotrichous ciliates and a tintinnid ciliate, formaldehyde caused less shrinkage than glutaraldehyde or acid Lugol's solution. With the aldehyde fixatives, the microflagellates were found to shrink more than the ciliates. Differential effects of fixation on cell volumes may result in an underestimation of the biomass of certain protozoan taxa in natural samples.     

PLANT MICROTECHNIQUE: SOME PRINCIPLES AND NEW METHODS

Some easily seen structural features of living plant cells are destroyed or badly distorted by most of the common fixatives and embedding media used in plant histology. In stained sections of plant tissues fixed in FAA (formalin-acetic acid-alcohol mixtures) and embedded in paraffin wax, for example, mitochondria and fine transvacuolar strands of cytoplasm are usually not visible. Many structural features such as these can be preserved, however, with suitable fixatives and embedding media. Specifically we recommend fixation in non-coagulant fixatives (e.g., osmium tetroxide, acrolein, glutaraldehyde, formaldehyde) and the use of plastics as embedding media, and we describe in detail a method of fixation in acrolein and embedding in glycol methacrylate polymer. In a wide range of plant specimens prepared in this way, stained sections 1–3 microns thick showed excellent preservation of tissue and cell structures.     

Antigen retrieval of basement membrane proteins from archival eye tissues.

Antigen retrieval (AR) methods can unmask tissue antigens that have been altered by fixation, processing, storage, or resin interactions. This is particularly important in the study of archival tissues, because primary fixatives and storage times may vary among specimens. We performed an electron microscopic study of basement membrane components of the aqueous humor drainage pathways from archival eye tissue. AR (heated citrate buffer, pH 6.0, LR White resin) increased the amount of label of collagen IV and fibronectin in tissue fixed in four different fixatives, including those containing glutaraldehyde. Labeling density was approximately doubled after AR for most fixatives, with the largest increase for tissues fixed in 4% paraformaldehyde/2% glutaraldehyde. Duration of storage time for archival tissues did not affect AR results. AR did not change the components of the extracellular matrix labeled; no "new" components were labeled after AR. We conclude that AR in citrate buffer can be used on selected extracellular matrix antigens to enhance label that would otherwise be lost due to fixation and storage.     

Establishment of HEp-2 cell preparation for automated analysis of ANA fluorescence pattern.

BACKGROUND: Identification of antinuclear antibodies (ANAs) has large clinical importance for the assessment of autoimmune diseases. HEp-2 cell preparations on microscopic slides are commonly used as antigenic substrate. Methods used for cell preparation are important for ANA pattern analysis; however, these methods differ widely and are mostly not specified. METHODS: HEp-2 cells were fixed using acetic acid-ethanol, methanol-acetone, acetone, formaldehyde, paraformaldehyde, or glutaraldehyde. Morphological analysis was done after haematoxylin-eosin staining and DAPI-staining of cell nuclei. RESULTS: The results demonstrate a high variability of cell and nuclear morphology depending on the used fixatives. Aldehyde fixatives conserved the cell structures best, acetone fixatives revealed remarkable changes. CONCLUSIONS: After selecting appropriate fixation procedures to preserve nuclear structures further experiments are necessary to find out which fixation procedure preserves the disease-linked antigens the best way and are, therefore, suitable to be used in ANA-testing of AABs.     

Fixation of early ascarid embryos for electron microscopic research

Ascaris embryos represent a classical object in embryology, but their ultrastructure has not been so far studied because their sheets are not permeable to fixatives used for electron microscopy. Thus, the fixation with glutaraldehyde for 24 hours followed by a 24 hour OsO4-fixation led to osmification of 1% embryos. The osmification of 100% embryos was achieved after addition of detergents, sodium dodecylsulfate or Triton X-100 to aldehyde fixative. The best fixation was povided using sodium dodecylsulfate judging from ultrastructure preservation.