HISTOLOGICAL STAINING OF LIPIDS FOR THE LIGHT AND ELECTRON MICROSCOPE

1. It is generally agreed that the blackening of osmium tetroxide by unsaturated lipid is too unpredictable to demonstrate lipid in tissues.
2. At neutral pH osmium tetroxide combines with the double bonds in the lipoproteins of cellular membranes (mitochondria, etc.) and the deep colour reaction of ethyl gallate with this osmium provides good staining of lipid for the light microscope.
3. Osmium taken up by tissue proteins at neutral pH is only a small fraction of that taken up by the lipid. (After acid fixatives osmium tetroxide is a general protein stain.)
4. The uptake of Sudan black B by partition from dilute solution is a specific test for lipid, but in normally fixed tissue most of the structural lipid is 'bound' and is not accessible to the dye.
5. Cautious treatment of fixed tissue with dilute sodium hypochlorite will unmask this lipid for viewing by the light microscope.
6. Direct fixation with neutral osmium tetroxide is an effective method for visualizing lipid for the electron microscope (as in the ethyl gallate method for the light microscope). But the poor penetration of osmium limits its use in this way.
7. After formol/glutaraldehyde fixation much of the lipid in the tissues is 'bound' and does not take up osmium. It can be unmasked by a saturated aqueous solution of thymol.
8. The unmasked lipid can then be rendered more osmiophil by partition in a solution of the highly unsaturated terpene farnesol, thus increasing the uptake of osmium in a renewed application.
9. Some of the novel observations on tissue lipids made by these methods are reviewed.     

Osmium tetroxide/p-phenylenediamine staining of nucleoli and Balbiani Rings in Chironomus salivary glands.

This paper deals with the application of the osmium tetroxide fixation followed by p-phenylenediamine treatment to salivary gland cells from Chironomus larvae. After this procedure, cytoplasm, nucleoli and Balbiani rings show a high degree of staining both in light and electron microscopy, while chromatin remains unstained. Ethanol fixation followed by osmium tetroxide/p-phenylenediamine does not modify the above mentioned staining pattern. Under these conditions, extractive procedures for lipids do not affect the osmiophilia of nucleoli and Balbiani rings, while RNase or trichloroacetic acid treatment decreaes the staining degree of these structures. In osmium tetroxide/p-phenylenediamine treated salivary glands, the highest contrast within nuclei is seen to occur in the pars granulosa from normal or segregated nucleoli, as well as in Balbiani ring granules, which appear either as hollow granules or with a bipartite or horseshoe-like structure.     

Osmium tetroxide/p-phenylenediamine staining of nucleoli and balbiani rings in Chironomus salivary glands

Summary This paper deals with the application of the osmium tetroxide fixation followed by p-phenylenediamine treatment to salivary gland cells from Chironomus larvae. After this procedure, cytoplasm, nucleoli and Balbiani rings show a high degree of staining both in light and electron microscopy, while chromatin remains unstained. Ethanol fixation followed by osmium tetroxide/p-phenylenediamine does not modify the above mentioned staining pattern. Under these conditions, extractive procedures for lipids do not affect the osmiophilia of nucleoli and Balbiani rings, while RNase or trichloroacetic acid treatment decreaes the staining degree of these structures. In osmium tetroxide/p-phenylenediamine treated salivary glands, the highest contrast within nuclei is seen to occur in the pars granulosa from normal or segregated nucleoli, as well as in Balbiani ring granules, which appear either as hollow granules or with a bipartite or horseshoe-like structure.     

Chemical analysis of osmium tetroxide staining in adipose tissue using imaging ToF-SIMS

Osmium tetroxide (OsO₄) is a commonly used stain for unsaturated lipids in electron and optical microscopy of cells and tissues. In this work, the localization of osmium oxide and specific lipids was independently monitored in mouse adipose tissue by using time-of-flight secondary ion mass spectrometry with Bi cluster primary ions. Substance-specific ion images recorded after OsO₄ staining showed that unsaturated C18 fatty acids were colocalized with osmium oxide, corroborating the view that osmium tetroxide binds to unsaturated lipids. In contrast, saturated fatty acids (C14, C16 and C18) and also unsaturated C16 fatty acids show largely complementary localizations to osmium oxide. Furthermore, the distributions of saturated and unsaturated diglycerides are consistent with the specific binding of osmium oxide to unsaturated C18 fatty acids. The abundance of ions, characteristic of phospholipids and proteins, is strongly decreased as a result of the osmium staining, suggesting that a large fraction of these compounds are removed from the tissue during this step, while ions related to fatty acids, di- and triglycerides remain strong after osmium staining. Ethanol dehydration after osmium staining results in more homogeneous distributions of osmium oxide and unsaturated lipids. This work provides detailed insight into the specific binding of osmium oxide to different lipids.     

Physical studies of phospholipids. 3. Electron microscope studies of some pure fully saturated 2,3-diacyl-DL-phosphatidyl-ethanolamines and phosphatidyl-cholines

On heating pure, fully saturated 2,3-diacyl-DL-phosphatidyl-ethanolamines and 2,3-diacylphosphatidyl-cholines (lecithins) in water to the transition temperature at which large endothermic heat changes occur, they are observed, by light microscopy, to form myelin figures. This result is discussed in terms of the large difference in the transition temperature for "melting" of the hydrocarbon chains of unsaturated and saturated phospholipids and is illustrated by means of differential thermal analysis (D.T.A.) curves. These structures have been examined by electron microscopy after negative staining and after reaction with osmium tetroxide. Typical phospholipid lamella structures are seen in the phosphatidylcholines after negative staining, and in the phosphatidyl-ethanolamines after both negative staining and osmium fixation. The distances across these lamellae have been measured. Some preliminary investigations of the nature of the osmium tetroxide reaction with the phosphatidyl-ethanolamines have been made.     

Ruthenium red as a stain for electron microscopy. Some new aspects of its application and mode of action.

Commercial ruthenium red has been tested for its purity by spectrophotometry. Impurities detected by this method could be abolished by nitric acid-precipitation of ruthenium brown. This substance has no effect on cell surface staining and converts almost completely to ruthenium red under the conditions used in electron microscopy. It was found, by photometric analysis, that in the ruthenium red-osmium tetroxide-cacodylate combination, generally used for cell surface staining, chemical reactions between ruthenium red and osmium tetroxide occur. As aerial oxidation of hexammineruthenium2+ leads to a product with some surface staining capability, it is suggested that an oxidized product of ruthenium red is responsible for binding to cellular components, and that a reduced product of osmium tetroxide gives an additional contrast enhancement. In ruthenium red-osmium dioxide combinations ruthenium red seems to bind to cell surfaces without any molecular alteration, and contrast is gained by the model proposed by Blanquet (1976b). The latter method could open a way for investigating the binding of ruthenium red to certain natural compounds involved in calcium transport, as postulated by a number of authors. Both ruthenium-osmium combinations differ in their cell surface staining ability. The ruthenium red-osmium dioxide combination tends to form distinct subunits, whereas the osmium tetroxide variety stains homogeneously. In combination with osmium dioxide, the surface staining is affected by EDTA, and, in contrast to osmium tetroxide, a successive application of ruthenium red and osmium dioxide as possible.     

Osmium dependent argentaffin staining of lysosomes

Summary Lysosomes stain with the argentaffin reaction after fixation with glutaraldehyde followed by osmium tetroxide. The reaction works well both at the level of the light and electron microscope. Control experiments show that this argentaffinity is caused by reduced osmium tetroxide. No staining could be observed in freeze-dried material, in tissues fixed only with glutaraldehyde, or after bleaching of the sections with hydrogen peroxide solutions. In the electron microscope, the population of lysosomes appears heterogeneous as related to the density of silver deposits over the organelles. No correlation is found between size and argentaffinity of lysosomes. X-ray microanalysis of sections from glutaraldehyde/osmium tetroxide fixed material reveals significantly higher amounts of osmium in lysosomes, as compared to other cell organelles (e.g. peroxisomes or mitochondria). A significant peak for silver is observed in lysosomes after treatment of the sections with ammoniacal silver solution, whereas the signal for osmium is reduced. Amounts of sulphur are too low to be detected in lysosomes. It is concluded that argentaffin staining of lysosomes is an osmium dependent reaction.Parts of these results have been presented as a poster during the 20th Congress of Electron Microscopy, joint session of the Austrian Society of Electron Microscopy and the German Society of Electron Microscopy, August 23–28, 1981, Innsbruck, Austria     

INTRAMITOCHONDRIAL FIBERS WITH DNA CHARACTERISTICS : I. Fixation and Electron Staining Reactions

Chick embryo mitochondria, studied with the electron microscope, show crista-free areas of low electron opacity. These areas are observable after fixation with osmium tetroxide, calcium permanganate, potassium permanganate, formaldehyde, acrolein, acrolein followed by osmium tetroxide, uranyl acetate followed by calcium permanganate, and acetic acid-alcohol. Staining of sections with lead hydroxide or uranyl acetate, or with both, resulted in an increased density of a fibrous material within these areas. The appearance of the fibrous structures varied with the fixative employed; after fixation with osmium tetroxide the material was clumped and bar-like (up to 400 A in diameter), whereas after treatment of osmium tetroxide-fixed tissues with uranyl acetate before dehydration the fibrous structures could be visualized as 15 to 30 A fibrils. Treatment with ethylenediaminetetraacetate (EDTA) in place of uranyl acetate coarsened the mitochondrial fibrils. After fixation with calcium permanganate or potassium permanganate, or a double fixation by uranyl acetate followed by calcium permanganate, the fibers appeared to have a pattern and ultrastructure similar to that observed after the osmium tetroxide-uranyl acetate technique, except that some of them had a slightly greater diameter (up to 50 A). Other fixatives did not preserve the fibers so well. The fibers appeared strongly clumped by formaldehyde fixation, and were difficult to identify after fixation with acrolein or acetic acid-alcohol. The staining of nucleic acid-containing structures by uranyl acetate and lead hydroxide was improved by treatment of osmium tetroxide-fixed sections with hydrogen peroxide, and the mitochondrial fibers also had an increased density in the electron beam after this procedure. The staining characteristics suggest the fibrous material of chick embryo mitochondria to be a nucleic acid-containing structure, and its variable appearance after different fixations parallels that previously reported, or described in this paper, for the nucleoplasm of bacteria and blue-green algae. The results, in addition to those described in the accompanying communication, indicate that these mitochondria contain DNA.     

Ruthenium red as a stain for electron microscopy. Some new aspects of its application and mode of action

Summary Commercial ruthenium red has been tested for its purity by spectrophotometry. Impurities detected by this method could be abolished by nitric acid-precipitation of ruthenium brown. This substance has no effect on cell surface staining and converts almost completely to ruthenium red under the conditions used in electron microscopy. It was found, by photometric analysis, that in the ruthenium red-osmium tetroxide-cacodylate combination, generally used for cell surface staining, chemical reactions between ruthenium red and osmium tetroxide occur. As aerial oxidation of hexammineruthenium²⁺ leads to a product with some surface staining capability, it is suggested that an oxidazed product of ruthenium red is responsible for binding to cellular components, and that a reduced product of osmium tetroxide gives an additional contrast enhancement.In ruthenium red-osmium dioxide combinations ruthenium red seems to bind to cell surfaces without any molecular alteration, and contrast is gained by the model proposed by Blanquet (1976b). The latter method could open a way for investigating the binding of ruthenium red to certain natural compounds involved in calcium transport, as postulated by a number of authors.Both ruthenium-osmium combinations differ in their cell surface staining ability. The ruthenium red-osmium dioxide combination tends to form distinct subunits, whereas the osmium tetroxide variety stains homogeneously. In combination with osmium dioxide, the surface staining is affected by EDTA, and, in contrast to osmium tetroxide, a successive application of ruthenium red and osmium dioxide as possible.     

Cellular membrane contrast and contrast differentiation with osmium triazole and tetrazole complexes

Summary Addition of heterocyclic nitrogen compounds to the classical osmium tetroxide postfixation medium, applied after glutaraldehyde fixation, results in enhanced membrane contrast in ultrathin sections of liver tissue. The addition of similar compounds to potassium osmate solutions, results in contrast differences in some cellular membranes. The membranes of the rough endoplasmic reticulum, the nuclear envelope and the plasma membrane acquire contrast, while the mitochondrial membranes do not. The apolar regions of membranes are contrasted when osmium tetroxide is combined with heterocyclic nitrogen compounds, whereas the polar regions are contrasted by combinations of potassium osmate with these compounds. This polar membrane contrast is probably due to the presence of an amino-group in the heterocyclic nitrogen compounds. Compounds without the amino-group do not contrast membranes, although the glycogen is contrasted.X-ray microanalysis served to establish the relative osmium content in contrasted glycogen, and showed that such nitrogen compounds play a role in complexation of cations in aldehyde-fixed tissues. Electron spectroscopy for chemical analysis (ESCA) measurements of isolated muscle glycogen show that after treatment with various osmium tetroxide or potassium osmate solutions, hexavalent and quadrivalent osmium species are present in the glycogen. The presence of (heterocyclic) nitrogen compounds in such solutions stabilizes certain osmium valency species, and this may account for the contrast observed.     

Imidazole-buffered osmium tetroxide: an excellent stain for visualization of lipids in transmission electron microscopy

Summary The usefulness of imidazole-buffered osmium tetroxide as a stain for lipids in transmission electron microscopy has been investigated. Rat liver and other tissues were fixed by perfusion with glutaraldehyde and post-fixed with osmium-imidazole and the appearance of lipid droplets was compared with that after post-fixation in unbuffered aqueous osmium tetroxide or an osmium solution buffered otherwise. Prominent electron-opaque staining of lipid droplets and of lipoprotein particles was noted after post-fixation with 2% osmium-imidazole, pH 7.5, for 30 min. The lipid droplets appeared well circumscribed with no evidence of diffusion. In contrast, the intensity of staining was much less and there was some diffusion around lipid droplets in material post-fixed in aqueous or cacodylate-buffered osmium tetroxide. Spot tests on filter paper revealed that unsaturated fatty acids, especially linolenic and linoleic acids reacted more intensely with osmium-imidazole than with aqueous osmium tetroxide. These findings demonstrate that osmium-imidazole provides an excellent stain for lipids in transmission electron microscopy and that most probably it stains lipids with unsaturated fatty acids.     

THE STAINING OF THIN SECTIONS OF MOUSE PANCREAS PREPARED BY THE FERNÁNDEZ-MORÁN HELIUM II FREEZE-SUBSTITUTION METHOD

Small pieces of mouse pancreas were rapidly frozen in helium II, substituted in methanol at -75°C., and embedded in methacrylate by ultraviolet polymerization in the cold. The unstained cells show a structure similar to that after OsO₄ fixation, except that the RNP particles have little or no contrast and the mitochondria and Golgi zones appear as grey areas without internal structure. After staining the sections by floating them on solutions of lead acetate or osmium tetroxide, there is an increase in contrast of RNP particles, ergastoplasmic membranes, and zymogen granules. Mitochondrial and Golgi membranes, zymogen granule membranes, and a membrane along the outside of the ergastoplasmic cisterna appear in negative contrast. The structure of the ergastoplasm, the existence of RNP particles, and the production of negative contrast are discussed. A modification of Gomori's method for acid phosphatase produces a lead deposit around the periphery of the zymogen granules. Possibly this deposit does not represent the true site of the enzyme, but the results show the feasibility of histochemistry at the level of resolution of the electron microscope.     

Localization of the synaptonemal complex under the light microscope

The use of osmium tetroxide fixation followed by postreatment with p-phenylenediamine gives an opportunity of locating the synaptonemal complex (SC) under the light microscope in mouse testes and Allium cepa anthers. When semi-thin sections from these materials were observed under phase contrast optics or dark field microscopy, fine threads in the pachytene nuclei were clearly visible. Post-staining of semi-thin sections with ammoniacal silver increased the contrast of the SC and allowed for observations using a bright field illumination. Ultrathin sections of osmium tetroxide/ p-phenylenediamine treated material showed that, under the electron microscope, this technique stains preferentially elements of the synaptonemal complex, while the surrounding chromatin remains unstained.     

Method of disinfecting plague-infected fleas in preparation for electron microscopic study

During fixation of fleas infected with plague agent (with preliminary cut heads, limbs and posterior part of the abdomen) in 2.5% glutaric dialdehyde or 2% osmium tetroxide their disinfection was obtained in two days. After double fixation with 2-hour exposure in each of these fixators disinfection of the material was acheived only after additional 2-day maintenance in 70% ethyl alcohol. Fleas, which had been placed into fixators or in 70% ethyl alcohol after double fixation without preliminary dissection, were disinfected completely only in 10 days.     

A simple impregnation technique for thin and semithin enterochromaffin cells in sections

Constant, intense and precise impregnation of enterochromaffin (EC) cells was achieved simply by floating thin or semithin sections of gut mucosa, fixed in osmium tetroxide or in glutaraldehyde with postfixation in osmium, on a silver nitrate or proteinate solution. EC cells alone showed impregnation in the light microscope. In the electron microscope, impregnation affected not only the secretory granules of EC cells but also, although much more faintly, those of other, non-EC cells (D, X, D1, G and other cells). Lysosomes also showed partial or total reactivity. Oxidation reduced but did not entirely suppress EC cell staining and had no effect on non-EC endocrine cell staining. Since the reaction did not occur with glutaraldehyde alone, osmium appeared to be a crucial component of the process. These findings should be borne in mind in applying Thiery's method for vicinal glycol groups to the type of study material used in these experiments.     

A simple impregnation technique for thin and semithin enterochromaffin cells in sections

Summary Constant, intense and precise impregnation of enterochromaffin (EC) cells was achieved simply by floating thin or semithin sections of gut mucosa, fixed in osmium tetroxide or in glutaraldehyde with postfixation in osmium, on a silver nitrate or proteinate solution. EC cells alone showed impregnation in the light microscope. In the electron microscope, impregnation affected not only the secretory granules of EC cells but also, although much more faintly, those of other, non-EC cells (D, X, D₁, G and other cells). Lysosomes also showed partial or total reactivity. Oxidation reduced but did not entirely suppress EC cell staining and had no effect on non-EC endocrine cell staining. Since the reaction did not occur with glutaraldehyde alone, osmium appeared to be a crucial component of the process. These findings should be borne in mind in applying Thiery's method for vicinal glycol groups to the type of study material used in these experiments.     

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.     

The distribution of lipid in the cell structure: An improved method for the electron microscope

An improved partition method for visualizing lipid consists in fixing tissues in paraformaldehyde-glutaraldehyde followed by osmium tetroxide. Three progressive grades of lipid staining are then obtained: (i) by renewed osmium tetroxide alone, (ii) by partition in myrcene or farnesol solutions followed by renewed osmium, (iii) by saturated thymol in sucrose followed by partition and renewed osmium. No additional metallic stains are used. The thymol treatment in (iii) renders ‘masked’ lipid accessible to partition—the effect being regulated as required by time and temperature. Thymol used before the first osmium facilitates lipid extraction which provides a complementary test for lipid. The possibilities of the method have been demonstrated on sections of familiar tissues of insect (mainly Rhodnius, Hemiptera) and mammal (mouse). By and large the results support what is known already about the distribution of lipid in cells, but observations on lipid in muscle fibres, in the nucleolus and chromatin, in the cells of the adrenal cortex, in the lung and intestine suggest that the method might prove a source of new information.     

Spermatogenesis in animals as revealed by electron microscopy

Summary Testes of the pond snail, Cipangopaludina malleata Reeve, were fixed in 1% osmium tetroxide, 3% permanganate, or 4% formaldehyde followed by 1% osmium tetroxide, each being buffered to pH 7.2 with Veronal-acetate or Sörensen's phosphate buffer. On the other hand, testes fixed with 4% formaldehyde adjusted to pH 7.2 with 0.075 M Na-cacodylate were incubated in Novikoff-Goldfischer medium for demonstrating thiamine pyrophosphatase, uridine or inosine diphosphatase, uridine monophosphatase or adenosine triphosphatase. The specimens incubated were postfixed in 1% osmium tetroxide buffered to pH 7.2 with Veronal-acetate buffer. Thin sections of the epoxy Epon resin-embedded tissue were stained either singly with saturated aqueous uranyl acetate or doubly with saturated aqueous uranyl acetate followed by lead citrate.In a concentric lamellar structure consisting of the granular endoplasmic reticulum in the cytoplasm of early atypical spermatids, disappearance of ribosomes attached to the outer surface of cisternae seems to have initiated at the central part of the structure, and the cisterna-attached ribosomes seem to participate in the formation of dense granules appearing in the vesicles representing the endoplasmic reticulum of atypical spermatids.The Golgi apparatus of the atypical spermatids in the advanced stages of development is composed of at least three different layers, the central part consisting of an amorphous material, the following lamellar and vesicular elements, and the peripheral fine vesicles.It has been assumed that the mechanism by which the nucleic acid, especially DNA is converted into the polysaccharide might be attributed to the function of the Golgi apparatus, because the transformation of dense granules into less dense granules as well as diphosphatase activities have been detected within the Golgi apparatus.This study was supported by Grant GM-8327-06 from the United States Public Health Service.