Quantitative assessment of cellular changes provoked by microwave enhanced fixation of parathyroids

Rat parathyroids fixed by microwave enhancement, i.e. microwave irradiation in the presence of glutaraldehyde for 8 s and postfixation with OsO4 after a delay of 5 min, were compared with parathyroids fixed by perfusion with glutaraldehyde followed by immersion in glutaraldehyde and finally in OsO4. Morphometric analysis revealed that microwave enhanced fixation led to a larger mean cell volume, to larger cell surface area, and to larger surface area in membranes of RER and secretory granules. Though it is not known by which method parathyroid cells are conserved closer to the living state it is obvious that microwave enhanced fixation retains more membranes but provokes centrifugal dislocation of membranes mimicking exocytosis.     

Relative speed of fixation of glutaraldehyde and osmic acid in plant cells measured by grana appearance in chloroplasts

Summary Brief fixation in a mixture of glutaraldehyde and OsO₄ caused stacked chloroplast grana membranes in leaf cells of wheat, barley, tobacco, maize, cowpea, pigweed or bean plants to distend and vesiculate. Fixation with glutaraldehyde followed by OsO₄ prevented this fixation artifact. In a fixative mixture, OsO₄ apparently reacted with cell contents before glutaraldehyde.     

Bacterial mesosomes: Real structures of artifacts?

The ultrastructural study of membrane organization in gram-positive bacteria related to the OsO₄ fixation conditions revealed that large, complex mesosomes are observed only when the bacteria are subjected to an initial fixation with 0.1% OsO₄ in the culture broth, as in the prefixation step of the Ryter-Kellenberger procedure. Evidence was obtained suggesting that the large mesosomes are produced by this prefixation. The kinetic study of the membrane morphological alterations occurring during the prefixation of Bacillus cereus with 0.1% OsO₄ in the culture broth showed that the amount of mesosome material increases linearly from zero to a maximum observed at 1.7 min of prefixation and that at about this time a maximum is reached for the number of mesosomes per unity of cell area and for the average individual mesosome area. The large mesosomes observed in gram-positives fixed by the complete Ryter-Kellenberger procedure would be the result of the membrane-damaging action of 0.1% OsO₄. Such damaging action was deduced from the observation that 0.1% OsO₄ quickly lyses protoplasts and induces a quick and extensive leakage of intracellular K⁺ from B. cereus and Streptococcus faeculis. In support of that interpretation is the observation that in bacteria subjected to several membrane-damaging treatments, mesosome-like structures are seen after three different fixation procedures. In bacteria initially fixed with 1% OsO₄, 4% OsO₄ or 2.5% glutaraldehyde, no large, complex mesosomes are observed, small and simple invaginations of the cytoplasmic membrane being present. The size of these minute mesosomes is inversely proportional that causes of fixation. Uranyl acetate was found among the studied fixatives the one to the rate the least damage to bacterial membranes. This fixative satisfactorily preserves protoplasts. In bacteria initially fixed with uranyl acetate no mesosomes were found. The results of the present work throw serious doubts on the existence of mesosomes, both large and small, as real structures of bacterial cells. It is proposed that a continuous cytoplasmic membrane without infoldings (mesosomes) would be the real pattern of membrane organization in gram-positives.     

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.     

Parathyroid cell variants may be provoked during immersion fixation

Summary Parathyroid glands of cattle, dogs, cats, mice and rats were immersed in glutaraldehyde or mixtures consisting of glutaraldehyde, formaldehyde and acrolein in either Na-phosphate, Na/K-phosphate or Na-cacodylate buffer, and postfixed with OsO₄ in the same buffers or, alternatively, in s-collidine.Excellent preservation of bovine, feline and murine parathyroid glands was achieved with fixation mixtures containing 1% glutaraldehyde, 1.5–2% formaldehyde and 2.5–5% acrolein in 0.1 M Na-cacodylate with or without Ca²⁺ and Mg²⁺, Na-phosphate or Na/K-phosphate at 4°C followed by postfixation with 1% OsO₄ in the same buffers or in s-collidine containing sucrose, Ca²⁺ and Mg²⁺. This procedure largely abolished the occurence of parathyroid cell variants. Bovine parathyroid glands were also satisfactorily preserved with 1% glutaraldehyde and 2% formaldehyde whereas 1% glutaraldehyde and 2.5 or 5% acrolein, lower or higher buffer osmolarity, or immersion at room temperature led to vacuolization of RER and to breakdown of membranes. In contrast, all fixation protocols led to the formation of dark and light cell variants and to multinucleated syncytial cells in dog and rat parathyroids. The results thus show that parathyroid cell variants arise during immersion fixation and that aldehydes, buffers and temperature are important factors for provoking parathyroid cell variants.     

Improved structural preservation in freeze-substituted sporidia ofUstilago avenae—a comparison with low-temperature embedding

Summary In the present study the cellular fine structure of freeze-substituted sporidia of the phytopathogenic fungusUstilago avenae is investigated by means of thin-section electron microscopy. A conventional embedding method using Spurr's low viscosity resin is compared with the recently developed methacrylate mixtures Lowicryl^® K 4 M and HM 20 resin. Generally, freeze-substitution yields improved preservation of fine structural details of the fungus compared to previously applied conventional fixation methods. Using double fixation during freeze-substitution prior to conventional embedding the fungal membrane system (plasmalemma, endoplasmic reticulum), organelles (mitochondria, nucleus etc.) and other cytoplasmic features (ribosomes, cytoskeleton) appear well resolved and smoothly contoured. Aldehyde fixed and Lowicryl embedded sporidia ofU. avenae resemble these double fixed fungal specimens fairly closely. The complete low-temperature preparation produces visualization of distinct cellular details although contrast reversal of cellular membranes (er, mitochondria etc.) is sometimes observed. In particular, fine structure resolution is enhanced in Lowicryl HM 20 embedded fungal cells. This is due also to significant improvement in staining of the cellular membranes, cytoskeleton (microfilaments and microtubules) and Golgi apparatus-like areas, using tannic acid. In case of the fungusU. avenae, freeze-substitution in combination with mild glutaraldehyde fixation and final low-temperature embedding in HM 20 resin prove suitable for improved preservation of cellular ultrastructure.Abbreviations cw cell wall - cy cytoplasm - FS freeze-substitution - FS-A GA/OsO₄ freeze-substitution and Spurr's LV-embedding - FS-B GA freeze-substitution and Lowicryl K 4 M LT-embedding - FS-C GA freeze-substitution and Lowicryl HM 20 LT-embedding - go Golgi apparatus-like body - GA glutaraldehyde - g glycogen deposit - l lipid droplet - LT low temperature - Lowicryl LT-embedding Lowicryl low-temperature embedding - Lowicryl LT-resin Lowicryl low-temperature resin - MeOH methanol - mf microfilament - mt microtubule - m mitochondrion - mvb multivesicular body - ne nuclear envelope - np nuclear pore - npl nucleoplasm - nu nucleolus - n nucleus - OsO₄ osmium tetroxide - pl plasmalemma - pr polyribosomes - Pb-citrate Reynolds' lead citrate - r ribosome - RT room temperature - rer rough endoplasmic reticulum - Spurr's LV-embedding Spurr's low viscosity embedding - Spurr's LV-resin Spurr's low viscosity resin - t tonoplast - Uac uranyl acetate - v vacuole     

Flagellar surface morphology ofChlamydomonas eugametos

Summary Flagellar surfaces ofChlamydomonas eugametos fixed in OsO₄ were compared to those fixed in glutaraldehyde by scanning and transmission electron microscopical techniques. They appeared to be quite different. Flagella fixed in OsO₄ had a pleated membrane that vesiculated when Tris was present during fixation. Flagella fixed in glutaraldehyde of various concentrations and buffer strengths, appeared to have disc-bearing appendages which were continuous with the membrane. On growing flagella the appendages occurred after 2 hours and they increased in size and complexity during the next 3 to 4 hours. No structural differences were observed between flagella of vegetative cells and those of gametes. Mating competence of gametes appeared to parallel the development of mature appendage-bearing flagella. The possibility that membrane vesicles, found in the cell culture medium, are derived from the flagellar appendages is discussed.     

ALTERATION OF THE CONFORMATION OF PROTEINS IN RED BLOOD CELL MEMBRANES AND IN SOLUTION BY FIXATIVES USED IN ELECTRON MICROSCOPY

The effects of several commonly employed fixatives on the three-dimensional conformations of two soluble proteins and the protein of intact red blood cell membranes have been studied by means of circular dichroism measurements in the spectral region of the peptide absorption bands. The fixatives used produced significant and parallel conformational changes in all of the proteins, in the increasing order: glutaraldehyde; OsO₄; glutaraldehyde followed by OsO₄; and KMnO₄. The last two treatments obliterated most of the helical character of the proteins. The significance of these observations to the preparation of specimens for electron microscopy is discussed.     

Fine Structure of Bacillus subtilis : I. Fixation

The fine structure of Bacillus subtilis has been studied by observing sections fixed in KMnO₄, OsO₄, or a combination of both. The majority of examinations were made in samples fixed in 2.0 per cent KMnO₄ in tap water. Samples were embedded in butyl methacrylate for sectioning. In general, KMnO₄ fixation appeared to provide much better definition of the boundaries of various structures than did OsO₄. With either type of fixation, however, the surface structure of the cell appeared to consist of two components: cell wall and cytoplasmic membrane. Each of these, in turn, was observed to have a double aspect. The cell wall appeared to be composed of an outer part, broad and light, and an inner part, thin and dense. The cytoplasmic membrane appeared (at times, under KMnO₄ fixation) as two thin lines. In cells fixed first with OsO₄ solution, and then refixed with a mixture of KMnO₄ and OsO₄ solutions, the features revealed were more or less a mixture of those revealed by each fixation alone. A homogeneous, smooth structure, lacking a vacuole-like space, was identified as the nuclear structure in a form relatively free of artifacts. Two unidentified structures were observed in the cytoplasm when B. subtilis was fixed with KMnO₄. One a tortuous, fine filamentous element associated with a narrow light space, was often found near the ends of cells, or attached to one end of the pre-spore. The other showed a special inner structure somewhat similar to cristae mitochondriales.     

INFLUENCE OF GLUTARALDEHYDE AND/OR OSMIUM TETROXIDE ON CELL VOLUME, ION CONTENT, MECHANICAL STABILITY, AND MEMBRANE PERMEABILITY OF EHRLICH ASCITES TUMOR CELLS

Effects of fixation with glutaraldehyde (GA), glutaraldehyde-osmium tetroxide (GA-OsO₄), and osmium tetroxide (OsO₄) on ion and ATP content, cell volume, vital dye staining, and stability to mechanical and thermal stress were studied in Ehrlich ascites tumor cells (EATC). Among variables investigated were fixation time, fixative concentration, temperature, osmolality of the fixative agent and buffer, total osmolality of the fixative solution, osmolality of the postfixation buffer, and time of postfixation treatment in buffer (Sutherland, R. M., et al. 1967. J. Cell Physiol. 69:185.). Rapid loss of potassium, exchangeable magnesium, and ATP, and increase of vital dye uptake and electrical conductivity occurred with all fixatives studied. These changes were virtually immediate with GA-OsO₄ or OsO₄ but slower with GA (in the latter case they were dependent on fixative temperature and concentration) (Foot, N. C. 1950. In McClung's Handbook of Microscopical Technique. 3rd edition. 564.). Total fixative osmolality had a marked effect on cell volume with OsO₄ but little or no effect with GA or GA-OsO₄. Osmolality of the buffer had a marked effect on cell volume with OsO₄, whereas with GA or GA-OsO₄ it was only significant at very hypotonic buffer osmolalities. Concentration of GA had no effect on cell volume. Osmolality of the postfixation buffer had little effect on cell volume, and duration of fixation or postfixation treatment had no effect with all fixatives. Freezing and thawing or centrifugal stress (up to 100,000 g) had little or no effect on cell volume after all fixatives studied. Mechanical stress obtained by sonication showed that OsO₄ alone produced poor stabilization and that GA fixation alone produced the greatest stabilization. The results indicate that rapid membrane permeability changes of EATC follow fixative action. The results are consistent with known greater stabilizing effects of GA on model protein systems since cells were also rendered relatively stable to osmotic stress during fixation, an effect not noted with OsO₄. After fixation with GA and/or OsO₄ cells were stable to osmotic, thermal, or mechanical stress; this is inconsistent with several earlier reports that GA-fixed cells retain their osmotic properties.     

SILVER IMPREGNATION OF ULTRATHIN SECTIONS FOR ELECTRON MICROSCOPY

A new procedure is described for silver impregnation of thin sections for electron microscopy. Sections of various tissues, fixed in OsO₄ and embedded in methacrylate, were treated with an ammoniacal silver solution, directly or after oxidation with periodic acid or hydrogen peroxide. After OsO₄ fixation all cellular membranous systems exhibit a primary argentaffinity probably due to the reduction of ammoniacal silver solution by the reduced osmium bound to unsaturated lipids. Bleaching the sections with hydrogen peroxide removes the argentaffinity of protoplasmic structures. Treatment of the sections with periodic acid results in decreased argentaffinity of protoplasmic components while the argentaffinity of metaplasmic structures is greatly enhanced. The latter procedure appears particularly useful for enhancing the contrast of basement membranes.     

THE ULTRASTRUCTURE OF LIPID-DEPLETED ROD PHOTORECEPTOR MEMBRANES

The structure of lipid-depleted retinal rod photoreceptor membranes was studied by means of electron microscopy. Aldehyde-fixed retinas were exhaustively extracted with acetone, chloroform-methanol, and acidified chloroform-methanol. The effect of prefixation on the extractability of lipids was evaluated by means of thin-layer chromatography and fatty acid analysis. Prefixation with glutaraldehyde rendered 38% of the phospholipids unextractable, while only 7% were unextractable after formaldehyde fixation. Embedding the retina in a lipid-retaining, polymerizable glutaraldehyde-urea mixture allows a comparison of the interaction of OsO₄ with lipid-depleted membranes and rod disk membranes which contain all their lipids. A decrease in electron density and a deterioration of membrane fine structure in lipid-depleted tissue are correlated with the extent of lipid extraction. These observations are indicative of the role of the lipid bilayer in the ultrastructural visualization of membrane structure with OsO₄. Negatively stained thin sections of extracted tissue reveal substructures in the lipid-depleted rod membranes. These substructures are probably the opsin molecules which are the major protein component of retinal rod photoreceptor membranes.     

The rhabdomeric microvilli of several arthropod compound eyes kept in darkness

Summary Electron microscopical studies were made on the fine structure of the rhabdomeric microvilli of the compound eyes of seven species of arthropods (Procambarus, Neocaridina, Caridina, Potamon, Artemia, Diestrammena, Drosophila) raised in complete darkness for 1–8 months or for successive generations, using various fixation techniques.The rhabdomeric microvilli of the individuals kept in darkness for a long period were regularly arranged as in normal eyes in the material prepared by double fixation with glutaraldehyde and OsO₄, whereas in those fixed solely by OsO₄ various forms of vesiculations were seen. The structural changes of the rhabdomere in darkness, which have been reported by several workers, were conceived to be an artefact caused by OsO₄ fixation.This work is supported by a grant from the U.S. Army Research and Development Group (Far East), Department of the Army (DA-CRD-AG-S92-544-67-G61).The authors wish to express their gratitude to Dr. S. Mori and Mr. T. Kuramoto for their help in supplying some of the materials. We are also indebted to Dr. C. J. C. Rees for correcting English of this paper.     

Silicotungstic acid for cytochemical localization of water soluble substance(s) of cholinergic motor nerve terminal

Summary Silicotungstic acid (STA), an electron dense substance and a powerful precipitating agent of quaternary ammonium salts such as choline and acetylcholine, was employed on the frog motor end-plate in order to prove that STA reacts with diffusible substance(s) in nerve terminals. Thus, STA treatment and osmium tetroxide (OsO₄) fixation were performed in three different ways. No reaction was detectable when STA treatment followed osmification, while simultaneous treatment with STA and OsO₄ darkened both presynaptic and synaptic vesicle membranes. When STA was employed directly on fresh tissues which were subsequently fixed by OsO₄, small black precipitates were observed in the synaptic vesicles and none on other synaptic structures. The possible reaction of STA with acetylcholine is discussed.     

Potency of microwave irradiation during fixation for electron microscopy

Summary Liver, skeletal muscle, peripheral nerves, pancreas, thyroid and adrenal cortex were prepared for electron microscopy employing microwave energy either during prefixation with glutaraldehyde or instead of prefixation. Microwave irradiation in the presence of glutaraldehyde in Na/K-phosphate or Na-cacodylate containing CaCl₂ and MgCl₂ led to distinct appearance of membranes, mainly plasma membrane, and membranes of SER, Golgi complex and mitochondria in liver, pancreas and muscle. The area of high quality fixation, however, was limited to the periphery of samples. On the other hand, SER was dilated in cells of the adrenal cortex, and RER markedly vacuolated in thyroid follicular cells.Microwave irradiation in the presence of Na/K-phosphate and subsequent osmication resulted in preservation of the ultrastructure in similar quality as was obtained by osmication without previous immersion in glutaraldehyde. However, the preservation of SER and Golgi complex in liver and pancreas, and of mitochondria in muscle was greatly improved. Small myelin sheaths remained intact whereas large ones showed focal disintegration.We consider that enhancement of fixation by microwave energy may greatly improve preservation of membranes in some tissues. Successful fixation depends on the use of glutaraldehyde during microwave irradiation, the type of buffer, the addition of ions to increase stabilization, the exposure time to heat, and on postosmication.     

ELECTRON MICROSCOPE OBSERVATIONS ON FROZEN-DRIED CELLS

To explore the problem of artefacts which may be produced during usual fixation, dehydration, and embedding, the authors have examined pancreas, liver, and bone marrow frozen at about -180°C., dried, at -55 to -60°C., embedded in methacrylate, sectioned, and floated on a formol-alcohol mixture. By these treatments the labile structure of living cells can be fixed promptly and embedded in methacrylate avoiding possible artefacts caused by direct exposure to chemical fixatives. Cell structures are ultimately exposed to a fixative when the sections are floated on formol-alcohol, but at this stage artefacts due to chemical fixation are expected to be minimized, as the fixatives act on structures tightly packed in methacrylate polymer. In the central zone of tissue blocks so treated, the cells are severely damaged by ice crystallization but at the periphery of the blocks the cell structure is well preserved. In such peripherally located cells, elements of the endoplasmic reticulum (ER), Palade's granules, homogeneously dense mitochondria, and nuclear envelopes and pores, can be demonstrated without poststaining with OsO₄. The structural organization in the nucleus is distorted by vacuolization. The mitochondrial membranes and cristae, cellular membrane, and the Golgi apparatus, however, are detected only with difficulty. The Golgi region generally appears as a light zone, in which some ambiguous structures are encountered. After staining the sections with OsO₄ or Giemsa solution, an inner mitochondrial structure which resembles the cristae seen in conventional OsO₄-fixed specimens appears, but the limiting membrane is absent. Treatment with OsO₄ or Giemsa solution also renders more distinct the membrane of the ER and Palade's granules but not the Golgi apparatus and cellular membrane. Treatment with ribonuclease results in the disappearance of Palade's granules. On the strength of these observations the authors conclude that OsO₄ fixation gives a satisfactory preservation of such cell structures as the nuclear envelope, endoplasmic reticulum, and Palade's granules, though it may induce slight swelling of these cell components.     

Size changes of mouse ova during preparation for morphometric studies in the electron microscope

Summary The diameters of oocytes during successive steps of preparation for electron microscopy were measured in the light microscope. During glutaraldehyde fixation the diameter of the ova mainly reflected the osmolarity of the fixative vehicle. An increase in the diameter of the ova occurred with postfixation in OsO₄ depending on time of postfixation and also on osmolarity and OsO₄ concentration. During ethanol dehydration the cell diameter decreased to its lowest value and remained unchanged after embedment in Epon. A procedure that minimizes ova size changes during preparation for electron microscopy is elaborated.This investigation was supported by NIH PL 480 Research Agreement No. 05-030-1.     

An Electron Microscope Study of Myelin Figures

In the electron microscope, thin sections of OsO₄-fixed myelin figures from the phospholipide fraction of human brain show a pattern of parallel dark lines with a repeating period of about 40 A. It is shown that the dark lines probably represent the reaction product of OsO₄ with double bonds in the fatty acid chains, thereby marking the central portion of one bimolecular lamella. The addition of globin results in dense lines 25 to 50 A wide that cover the surface of the myelin figures. When such a figure consists of only two bimolecular leaflets of lipide covered with globin, the structure shows striking similarity to the image of cell membranes in fixed tissue sections. A hypothetical schema is given of the molecular structure of the figure, and the distribution of OsO₄ in it.     

Ultrastructure of the Invasion of Eimeria magna Sporozoites into Cultured Cells*†‡

SYNOPSIS. Monolayers of bovine kidney cells were overlaid with Eimeria magna sporozoites and observed with phase-contrast optics until penetration of the cells by the parasites had begun. Cells and penetrating parasites were fixed with glutaraldehyde and OsO₄-containing ruthenium red, dehydrated, and embedded in situ. Cells being penetrated were selected for study in the electron microscope. The lack of intracellular staining with ruthenium red and intact plasmalemmas of cells being penetrated, was accepted as evidence that the sporozoites did not disrupt the plasma membranes. The sporozoite caused invagination of the host cell plasmalemma until the parasite was entirely within the cell, after which the invagination was sealed off by short pseudopodia enclosing the sporozoite within a membrane-lined vacuole inside the cell. Often myelin-forms, apparently of host cell origin, were seen in the space between the sporozoite and the cell.     

Immunogold labeling of cryosections from high-pressure frozen cells

Immunogold labeling of cryosections according to Tokuyasu (Tokuyasu KT. A technique for ultracyotomy of cell suspensions and tissues. J Cell Biol 1973;57:551–565), is an important and widely used method for immunoelectron microscopy. These sections are cut from material that is chemically fixed at room temperature (room temparature fixation, RTF). Lately in many morphological studies fast freezing followed by cryosubstitution fixation (CSF) is used instead of RTF. We have explored some new methods for applying immunogold labeling on cryosections from high‐pressure frozen cells (HepG2 cells, primary chondrocytes) and tissues (cartilage and exocrine pancreas). As immunolabeling has to be carried out on thawed and stable sections, we explored two ways to achieve this: (1) The section fixation method, as briefly reported before (Liou W et al. Histochem Cell Biol 1996;106:41–58 and Möbius W et al. J Histochem Cytochem 2002;50:43–55.) in which cryosections from freshly frozen cells were stabilized in mixtures of sucrose and methyl cellulose and varying concentrations of glutaraldehyde, formaldehyde and uranyl acetate (UA). Only occasionally does this method reveal section areas with excellent cell preservation and negatively stained membranes like Tokuyasu sections of RTF material. (Liou et al.) (2) The rehydration method, a novel approach, in which CSF with glutaraldehyde and/or osmium tetroxide (OsO₄) was followed by rehydration and cryosectioning as in the Tokuyasu method. Especially, the addition of UA and low concentrations of water to the CSF medium favored superb membrane contrast. Immunogold labeling was as efficient as with the Tokuyasu method.