The effect of glutaraldehyde fixation on the elucidation of the morphogenesis of annulate lamellae in oocytes ofRana pipiens

Summary Primary fixation of the frog oocyte with glutaraldehyde, compared to osmium tetroxide, alters the appearance of components involved in the morphogenesis of annulate lamellae. With glutaraldehyde, the outer layer of the nuclear envelope is connected with membranous laminae of variable length. Rounded blebs of the outer layer of the nuclear envelope are infrequently observed. Further, rather than clusters or rows of cytoplasmic vesicles as are observed in osmium tetroxide-fixed cells; numerous and long, smooth-surfaced lamellae are present in the ooplasm after glutaraldehyde fixation. The long membranous laminae then become concentrated in several ooplasmic packets. This is followed by the progressive alignment or orientation of the laminae within the packet. Eventually, those aligned and formerly smooth-surfaced lamellae are converted into annulate lamellae.This study was supported by research grants (HD-00699, GM-09229) and a Career Development Award from the National Institutes of Health, U.S. Public Health Service.     

A study of the ultrastructural organization of cytochromec-phospholipid membranes as revealed by various experimental treatments

Summary Two different types of cytochromec-phospholipid model membranes have been investigated by electron-microscopy. The preservation of the lamellar structure of the cytochromec plus phospholipid-water system after extraction of 88% phospholipids with aqueous acetone followed by only aldehyde fixation is revealed.Pronase digestion of this type of model membrane leads to removal of 80% of the protein and loss of ordered structures as revealed by aldehyde post-fixation.It is shown that the hydrated isooctane-soluble cytochromec-phospholipid complex retained the lamellar structures after extraction of 75% phospholipids followed by separate aldehyde and osmium tetroxide fixations. Pronase treatment of this type of model membrane leads to removal of 25 to 30% of the protein. After aldehyde fixation of these pronase-treated samples the triple-layered structures are preserved.The structural integrity of both types of model membranes after organic extractions with aldehyde pre- or post-fixation is thought to be the result of cross-linkage of the protein by aldehyde polymers on both surfaces and through lipid bilayers. Possible localization of cytochromec in investigated model membranes is discussed.     

The effects of various fixatives on the relative thickness of cellular membranes in the ventral lobe of the rat prostate

Synopsis A densitometric method was utilized in the measurement of the relative thickness of the cellular membranes in the ventral lobe of the rat prostate. Potassium permanganate, glutaraldehyde, osmium tetroxide, and ruthenium tetroxide solutions were used as fixatives. During preparation for electron microscopy, the tissues were given standardized treatments to reduce methodological errors; latex particles were applied to the thin sections to serve as reference particles of a known size. The most remarkable observation of the study was that the densitometric method yielded reproducible results and that the different fixatives gave significantly different values for the relative thickness of cellular membranes. Glutaraldehyde, or glutaraldehyde followed by ruthenium tetroxide post-fixation, gave the highest values for membrane thickness while osmium tetroxide and potassium permanganate gave the lowest values. Glutaraldehyde treatment, prior to osmium tetroxide or potassium permanganate post-fixations, rendered the membranes thicker than after osmium tetroxide and potassium permanganate treatments alone. Ruthenium tetroxide appeared to be very suitable for fixation of cellular membranes.     

Lipid staining for the electron microscope: a new method.

Tissues fixed in osmium tetroxide or in combined osmium and glutaraldehyde (Hinde), embedded in Spurr's medium, cut at 0-5-I mum and mounted in Farrants' gum medium containing ethyl gallate, show good staining of lipid-contaning structures (droplets of triglyceride, membranes, mitochondria, etc.) in the light microscope. Such preparations show moderate contrast in the electron microscope without further staining. But a specific increase in contrast in lipid-rich structures is obtained by partition of the tissues, before embedding, in 70% ethanol saturated with the monoterpene hydrocarbon myrcene, with or without the addition of 0-I % ethyl gallate, followed by osmium tetroxide. This method will visualize both saturated and unsaturated lipids, including waxes.     

The ultrastructure of Candida krusei

Various methods of chemical fixation and freeze-drying of Candida krusei were compared to determine the most appropriate method for the ultrastructural investigation of the thick walled organisms of this genus. Freeze-drying without chemical fixation was of little value because of insufficient variation in electron density. Potassium permanganate was able to penetrate the intact cell but failed to show cytoplasmic glycogen and lipid and some details of the cell wall. While normal glutaraldehyde, formaldehyde and osmium tetroxide treatment failed to permeate and preserve intracellular structures, several cycles of rapid freezing (–155°C) and thawing followed by glutaraldehyde fixation and osmium tetroxide post-fixation demonstrated the intracellular details of the majority of cells so treated.     

Atomic force microscopy investigation of fibroblasts infected with wild-type and mutant murine leukemia virus (MuLV)

NIH 3T3 cells were infected in culture with the oncogenic retrovirus, mouse leukemia virus (MuLV), and studied using atomic force microscopy (AFM). Cells fixed with glutaraldehyde alone, and those postfixed with osmium tetroxide, were imaged under ethanol according to procedures that largely preserved their structures. With glutaraldehyde fixation alone, the lipid bilayer was removed and maturing virions were seen emerging from the cytoskeletal matrix. With osmium tetroxide postfixation, the lipid bilayer was maintained and virions were observable still attached to the cell surfaces. The virions on the cell surfaces were imaged at high resolution and considerable detail of the arrangement of protein assemblies on their surfaces was evident. Infected cells were also labeled with primary antibodies against the virus env surface protein, followed by secondary antibodies conjugated with colloidal gold particles. Other 3T3 cells in culture were infected with MuLV containing a mutation in the gPr80(gag) gene. Those cells were observed by AFM not to produce normal MuLV on their surfaces, or at best, only at very low levels. The cell surfaces, however, became covered with tubelike structures that appear to result from a failure of the virions to properly undergo morphogenesis, and to fail in budding completely from the cell's surfaces.     

HYDROXYPROPYL METHACRYLATE, A NEW WATER-MISCIBLE EMBEDDING MEDIUM FOR ELECTRON MICROSCOPY

Aldehyde-fixed rat tissues were variously dehydrated and impregnated in water-miscible 2-hydroxypropyl methacrylate (HPMA) containing 3 to 20 per cent water and 0.1 per cent α,α-azobisisobutyronitrile as catalyst for subsequent polymerization with ultraviolet light. Heat polymerization was also effective. Blocks of embedded tissue readily gave ultrathin sections, which required staining by uranyl acetate and/or lead stains to give adequate contrast for electron microscopy. The ultrastructure of pancreas, kidney, muscle, and intestine was well preserved by aldehyde fixation alone. Use of postfixation in osmium tetroxide or direct osmium tetroxide fixation was unsatisfactory. The fine structure of aldehyde-fixed liver from fasted rats was well preserved, whereas that from normal rats showed considerable disorganization and collapse, apparently because of extraction of glycogen during the embedding procedure. Enzymatic extraction of proteins by pepsin and of ribonucleic acid by ribonuclease after either formaldehyde or glutaraldehyde fixation was rapidly effected by direct treatment of ultrathin sections with solutions of the enzymes. In contrast, no digestion of chromatin by deoxyribonuclease could be detected. In spite of this present limitation, HPMA appears to have several advantages over earlier water-miscible embedding media for electron microscopy and to be particularly suitable for ultrastructural cytochemistry.     

Structure of the nucleoid in cells of Streptococcus faecalis

The structure of the nucleoid of Streptococcus faecalis (ATCC 9790) was examined and compared in the unfixed and fixed states by immersive refractometry and electron microscopy. It appears from these studies that the nucleoid structure is much more centralized in unfixed chloramphenicol-treated (stationary-phase) cells than it is in cells in the exponential phase of growth. The more dispersed configuration of the exponential-phase nucleoid could be preserved by fixation in glutaraldehyde, but not in Formalin or in osmium tetroxide. One important factor in explaining these differences in preservation is that glutaraldehyde (but not Formalin or osmium tetroxide) can rapidly cross-link the amino groups of macromolecules in cells. It was also observed that osmium tetroxide resulted in a preferential breakdown of nascent ribonucleic acid. These results are interpreted as indicating that glutaraldehyde is able to stabilize the exponential-phase nucleoid before it assumes the more central appearance seen in osmium tetroxide- and Formalin-fixed cells. These results are discussed in terms of the proposed organization of the exponential-phase nucleoid in unfixed cells.     

THE EFFECTS OF RESERPINE AND HYPOXIA ON THE AMINE-STORING GRANULES OF THE HAMSTER CAROTID BODY

The carotid bodies from control, reserpine-treated, and hypoxia-treated hamsters were fixed with phosphate-buffered glutaraldehyde and osmium tetroxide, s-Collidine-buffered osmium tetroxide, or phosphate-buffered glutaraldehyde followed by potassium dichromate incubation. Following glutaraldehyde-osmium tetroxide fixation no differences in density or population of the electron-opaque granules in the glomus cells of either control or experimental animals were observed. With s-Collidine-buffered osmium tetroxide and the glutaraldehyde-dichromate technique a marked decrease in density without an appreciable reduction in number of granules was noted after reserpine treatment, while in hypoxia-treated hamsters the density and population of the granules were not different from those of the controls. The results indicate that reserpine depletes the amines without granule disappearance and that hypoxia does not affect the amine content of the granules. It is suggested that following glutaraldehyde-osmium tetroxide double fixation, persistence of the density of the granules in reserpine-treated animals is due primarily to the nonamine content, and that the amines in the glomus cells are probably not directly involved in the respiratory reflex.     

Glutaraldehyde fixation of central nervous tissue: an electron microscopic evaluation in the isolated rabbit retina

The isolated rabbit retina was studied electron microscopically after fixation with a 3% solution of glutaraldehyde in a 0.05 M S?rensen's phosphate buffer. In radial sections, the inner segments, nuclei, and synapses of the photoreceptor cells seemed similar in size to those from retinas that had been fixed in an isotonic solution containing 1 % crystalline osmium tetroxide in the incubating medium used for the isolation procedure. However, when the number of comparable structures was greatly increased by viewing them in tangential sections, the cellular shrinkage and mitochondrial swelling produced by this widely used, hypertonic, glutaraldehyde fixative were obvious.     

Fixation of Mature Spores of Clostridium botulinum

A triple fixation method using a sequential application of 15 or 30% formaldehyde, 6% glutaraldehyde, and 1% osmium tetroxide resulted in excellent fixation of mature spores of Clostridium botulinum.     

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     

The effects of 6-hydroxydopamine on the appearance of granulated vesicles in glomus cells of the rat carotid body

The glomus cells of the rat carotid body reveal an intense fluorescence after exposure to paraformaldehyde vapor and contain catecholamines. After initial fixation in glutaraldehyde, many granulated vesicles are seen in the glomus cells. After initial fixation in osmium tetroxide, most of the vesicles are depleted of their dense interiors and granulated vesicles occur infrequently. Administration of 6-hydroxydopamine followed by initial fixation in osmium tetroxide leads to the reappearance of dense interiors in virtually all vesicles. 6-Hydroxydopamine apparently is taken up by the membrane pump of the glomus cell and is incorporated into the amine storage granules, thereby displacing the endogenous monoamines. Osmium tetroxide does not dissolve the 6-hydroxydopamine from the vesicles, as it apparently does for the normal vesicular contents. The 6-hydroxydopamine does not fluoresce, hence 6-hydroxydopamine administration results in a decreased intensity of formaldehyde induced fluorescence in the glomus cells. Administration of reserpine after 6-hydroxydopamine treatment (and subsequent initial fixation in osmium tetroxide) depletes the previously restored dense material from the vesicles of the glomus cells. 6-Hydroxydopamine acts like a monoamine in that it is taken up by the glomus cell, incorporated into the vesicles, and can be depleted from the vesicles by reserpine.     

Ultrastructure of the concentric membrane system in Arthrinium aureum

An ultrastructural study was performed on Arthrinium aureum. The fungi were treated with glutaraldehyde and osmium tetroxide fixation. The hypha and conidia has a concentric membrane system which consisted of multiple membranes of a myelinoid appearance, and continued to the conidia and hypha plasma membrane. The fungi were also treated with periodic acid-alkaline bismuth (PABi) staining after glutaraldehyde and osmium tetroxide fixation. PABi positive materials were found on the marginal glycogen granules, the concentric membrane system and the conidia plasma membrane.     

On the stabilization by fixation of configurational states in beef heart mitochondria

The energized configuration of the cristal membrane of beef heart mitochondria can be maintained only as long as oxygen is available for electron transfer. When the oxygen supply is exhausted, the membrane undergoes a transition to the nonenergized configuration. Since the exhaustion of the available oxygen supply is complete in 5–20 sec, it is impossible to apply the method of sedimenting the mitochondria prior to fixation for studying the energized configurational states of mitochondria. The direct addition of glutaraldehyde followed by osmium tetroxide to the mitochondrial suspension is the most effective way of freezing the configurational state of the cristal membrane. Fixation with glutaraldehyde appears to be complete within 1–2 sec even at 0°. Osmium tetroxide alone can also freeze the energized configuration by fixation but the concentration of the fixative is critical. The problem of capturing the configurational state applies not only to energized transitions (nonenergized to energized) but also to nonenergized transitions (orthodox to aggregated). The freezing by fixation of the cristal membrane in the aggregated configuration is best accomplished by the sequential use of glutaraldehyde and osmium tetroxide. When the levels of glutaraldehyde and osmium tetroxide are respectively too low or too high, the mitochondrion will undergo a transition from the aggregated to the orthodox configuration before fixation is complete. Light-scattering studies provide an independent method for monitoring configurational changes in mitochondria; these light-scattering measurements confirm that the conditions for fixation which lead to stabilization of the energized state as judged by electron microscopy, also show maintenance of configuration as judged by absence of light-scattering changes after the fixatives are introduced. Reagents used in negative staining will induce the geometrical form of the energized configuration of the mitochondrion even under nonenergizing conditions. These reagents are thus unsuitable for use in studies of configurational transitions in mitochondria.     

An analysis of the contribution of the preparatory technique to the appearance of condensed and orthodox conformations of liver mitochondria

The structure and volume of isolated mitochondria embedded for electron microscopy during different respiratory states were analyzed in thin sections. Three different embedding methods were compared; osmium tetroxide fixation/acetone dehydration, glutaraldehyde fixation/acetone dehydration, and glutaraldehyde fixation-osmium tetroxide postfixation/acetone dehydration. Analysis of fresh mitochondria, isolated in a sucrose medium, revealed the presence of a homogeneous population with respect to structure when any of the three methods were applied. After fixation with osmium alone, or in combination with glutaraldehyde, nearly 100% of the mitochondria were in a "condensed" conformation. Mitochondria fixed with glutaraldehyde alone resulted in a population of mitochondria that had large spaces separating the two membranes of the cristae which corresponds to the condensed conformation as observed after osmium fixation. Transfer of the mitochondria to the incubation medium led to the appearance of two classes of mitochondria with respect to size. One class had a volume close to that observed when suspended in sucrose, and another class was present that was 30-45% larger. In osmium fixed or in double-fixed preparations, these small and large classes corresponded to "condensed" and "orthodox" forms of mitochondria respectively. When glutaraldehyde was used alone as the fixative, the two size classes were also present. However, the mitochondria were homogeneous with respect to structure. In these mitochondria, the width of the space that separated the cristae membranes had become reduced when compared to mitochondria suspended in sucrose. The two size classes were also present in samples of mitochondria prepared during both states 3 and 4. State 4 conditions did not lead to any significant increase of the number of condensed mitochondria. In state 3 preparations, 65-70% of the population were condensed. The condensed and orthodox forms could be related to normal and swollen forms of mitochondria. Conditions that led to a swelling also led to an increase in the number of orthodox mitochondria in osmium-fixed material. The different appearance of the mitochondria is explained by the different conditions for fixation of the mitochondria that exist when nonswollen and swollen mitochondria are fixed. This difference is particularly crucial in the case of osmium tetroxide due to the unique way this fixative, among generally used fixatives, denatures proteins.     

Parathyroid ultrastructure after aldehyde fixation, high-pressure freezing, or microwave irradiation

Parathyroid cell variants, commonly observed in parathyroid glands fixed by immersion in glutaraldehyde, are believed to be the result of cyclic changes in the course of parathyroid hormone secretion. Immersion of bovine parathyroid glands in a mixture consisting of 1% glutaraldehyde, 1.5% formaldehyde, and 2.5% acrolein, followed by post-fixation in 1% osmium tetroxide, resulted in high uniformity with only one cell variant, whereas the same fixation procedure led to disruption of cell membranes and formation of cell variants in rat parathyroids. Parathyroid glands of both cattle and rats prepared by high-pressure quick-freezing and subsequent freeze-substitution contained only one cell variant. Excellent preservation of the ultrastructure of bovine and rat parathyroids, also exhibiting only one cell variant, was achieved by microwave irradiation in the presence of 2.5% glutaraldehyde in Na-cacodylate followed by post-fixation with OsO4 in Na-cacodylate or s-collidine, both containing Ca2+ and Mg2+. Use of the appropriate buffer, as well as osmication, is essential for successful fixation utilizing microwave energy. The main effects are considered to be heating specimens within sufficient short periods and enhancement of subsequent osmium fixation. The results support the idea, arising after examination of perfusion-fixed parathyroid tissue, that parathyroid cell variants occur during improper aldehyde fixation rather than that they express functional diversity.     

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.     

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.     

PRESERVATION OF THE ULTRASTRUCTURE OF BACILLUS SUBTILIS BY CHEMICAL FIXATION AS VERIFIED BY FREEZE-ETCHING

The present study on the ultrastructure of Bacillus subtilis was undertaken in order to examine by means of the freeze-etching technique possible structural changes occurring during the chemical fixation procedure (Ryter-Kellenberger (R-K) fixation). Three stages were followed by freeze-etching, viz.: (a) fixation in osmium tetroxide, (b) fixation in osmium tetroxide and posttreatment with uranyl acetate, and (c) fixation in osmium tetroxide, posttreatment in uranyl acetate, and dehydration in a graded series of acetone. Preparations were made after each stage in the presence of 20% glycerol. Good preservation of ultrastructure was observed, after any of the three treatments, of the outer surface of the plasma membrane, and the inner surface of the plasma membrane. No alteration in fracturing properties could be observed. However, if we are to judge by the results of freeze-etching, any of the successive steps of the chemical fixation procedure achieve strong contrast between the nucleoplasmic region and the cytoplasm. Dependent on the quality of fixation, very delicately preserved DNA fibrils or strongly aggregated ones were seen. It appears that R-K fixation is capable of producing more or less distinctly visible changes in the native state of the nucleoplasm in young cells of B. subtilis.