Preservation of cartilage matrix proteoglycans using cationic dyes chemically related to ruthenium hexaammine trichloride.

We tested various cationic dyes chemically related to ruthenium hexaammine trichloride (RHT) [i.e., the RHT-cyclohexanedione complex (RHT-CC), pentaamine ruthenium N-dimethylphenylenediimine trichloride (PRT), tris-(bipyridyl)ruthenium (II) chloride (TRC), tris (bipyridyl) iron (II) chloride (TIC), and cobalt hexaammine trichloride (CHT)] for their effectiveness in precipitating cartilage matrix proteoglycans in situ. Dyes were introduced into media at the onset of processing and were present throughout both aldehyde fixation and osmium tetroxide post-fixation. Contrary to expectation, most of the dye-proteoglycan complexes generated and stable under aldehyde fixation conditions were found to be unstable during post-fixation despite the continuing presence of the dye. A similar phenomenon was also found for the cationic dyes commonly used for precipitation of proteoglycans in cartilage tissue sections (such as Acridine Orange, Alcian Blue, Azure A, Methylene Blue, and Ruthenium Red). Only two dyes, i.e., RHT and the newly tested RHT-CC, formed proteoglycan precipitates sufficiently stable to resist disruption and extraction during osmium tetroxide post-fixation. The latter may be particularly useful in semiquantitative analyses of proteoglycan content in unstained tissue sections owing to its intense brown-black color. For applications in which the osmium tetroxide post-fixation step may be omitted, TRC and PRT may also be valuable for semiquantitative histochemistry by virtue of their stable fluorescence and intense violet color signals, respectively.     

Simple and rapid methods for SEM observation and TEM immunolabeling of rubber particles.

We developed a method involving air-drying of a rubber suspension after fixation in glutaraldehyde-tannic acid and postfixation in osmium tetroxide for SEM observation. For TEM immunolabeling the suspension was air-dried after osmium-only fixation. Whereas conventional methods failed to satisfactorily stabilize rubber particles, the methods described here proved successful in preserving their integrity.     

Scanning electron microscope study ofTorulopsis ethanolitolerans prepared by glutaraldehyde—Thiosemicarbohydrazide procedure

Torulopsis ethanolitolerans subject to both the sparing and coarse heat treatment were studied in the scanning electron microscope. The reduction of adhesivity, increased permeability and higher rigidity of the yeast wall was achieved by an original glutaraldehyde—paraformaldehyde fixation, low osmolarity in vacuo and subsequent thiosemicarbohydrazide incubation, followed by addition of metal salt. The impregnation of the metal throughout the specimen due to the reaction of the thiosemicarbohydrazide with glutaraldehyde allowed viewing of small or intricate surface details of the yeast. Structural differences of the yeast processed by sparing and coarse heat treatment were shown to be better from the thiosemicarbohydrazide incubated samples compared to those that were prepared with osmium tetroxide.     

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.     

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.     

FURTHER ELECTRON MICROSCOPE STUDIES ON FIBRILLAR ORGANIZATION OF THE GROUND CYTOPLASM OF CHAOS CHAOS

Further evidence for fibrillar organization of the ground cytoplasm of Chaos chaos is presented. Fixations with osmium tetroxide at pH 6 or 8 and with glutaraldehyde at pH 6 or 7 were used on two preparations: (a) single actively streaming cells; (b) prechilled cells treated with 0.05% Alcian blue in the cold and returned to room temperature for 5–10 min. In addition, a 50,000 g pellet of homogenized cells was examined after fixation with glutaraldehyde-formaldehyde alone. In sections from actively streaming cells considerable numbers of filaments were observed in the uroid regions after glutaraldehyde fixation, whereas only traces of filaments were seen after osmium tetroxide fixation at either pH 6 or 8. Microtubules were not seen. In sections from dye-treated cells, filaments (4–6 mµ) and fibrils (12–15 mµ) were found with all three fixatives. The 50,000 g pellet was heterogeneous but contained both clumps of fibrils and single thick fibrils like those seen in the cytoplasm of dye-treated cells. Many fibrils of the same dimensions (12–15 mµ wide, 0.5 µ long) were also seen in the supernatant above the pellet. Negative staining showed that some fibrils separated into at least three strands of 4–6 mµ filaments.     

Electron microscopical demonstration of sulphated mucopolysaccharides in mouse tracheal cartilage with a diaminobenzidine-osmium tetroxide technique

Synopsis A diaminobenzidine-osmium tetroxide method for the demonstration of sulphated mucopolysaccharides has been tested at the electron microscopical level. The reaction (which involves treatment with diaminobenzidine in an acidic solution followed by oxidation with osmium tetroxide) has been carried out directly on ultra-thin sections of mouse tracheal cartilage embedded in water-soluble glycolmethacrylate. Sulphated mucopolysaccharides in the cartilage matrix were localized as a heavy, electron-dense precipitate. The method can be applied directly to sections, overcoming in this way the difficulties of penetration, and it seems to possess a higher specificity for sulphated mucopolysaccharides than that displayed by other techniques proposed previously for the ultrastructural demonstration of acid mucopolysaccharides.     

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.     

Use of tannic acid for the ultrastructural visualization of periplasm in gram-negative bacteria

Tannic acid mordanting reveals the periplasm, the area between the outer membrane and the inner membrane of gram-negative bacteria, Rhizobium sp., Escherichia coli and Enterobacter aerogenes, as an electron-dense layer continuous with the inner leaflet of the outer membrane. The method involves 18 hr of tannic acid treatment after fixation in aldehyde prior to osmium tetroxide postfixation, followed by conventional electron microscopy.     

Fine structure of the osteocyte capsule and of the wall of the lacunae in bone

Summary Bone tissue from femura of adult and old rats and from young mice, as well as from dogs, were fixed in osmium tetroxide, potassium permanganate, in an osmium tetroxide — potassium permanganate combination, and in glutaraldehyde followed by osmium tetroxyde — potassium permanganate. The results of the different fixatives were found to complement one another in such a way that existing controversies and uncertainties concerning the fine structure could be settled. This was especially true of the question whether or not the so-called capsule of the osteocyte contains collagen fibrils. Notwithstanding considerable variations in the structure of the capsule it was definitely shown that cross-banded fibrils are present in a mucopolysaccharide-containing ground substance. The material of the capsule corresponds, therefore, to the matrix of connective tissue in general, and its ground substance is, as in any connective tissue, the medium of transport between the blood and the tissue. In respect to the organic structures the intralacunar matrix is similar to the interlacunar mineralized matrix. In sections of demineralized bone, especially after osmium tetroxide fixation, the wall of the lacuna and canaliculi is marked by a dark line which is described as a special osmiophilic lamina. Since the same line, although thinner and less distinct, was found also in tissue fixed with agents other than osmic acid it was concluded that the osmiophilic lamina is a true structure which must be permeated by substances passing to and from the interlacunar matrix. The osmiophilic lamina belongs to a wider border zone which differs from the bulk of the mineralized matrix by its thinner and less tightly packed fibrils. Accordingly, the bone crystals were found to be less orderly arranged than those deeper inside the mineralized matrix. Bordering directly on the intralacunar pathway they were described as the coastal crystals and are believed to represent the labile bone minerals which are metabolically available without any change in the bone structure. The findings about the fine structure of the capsule of the osteocyte and of the wall of the lacunae were discussed in terms of the transport problems in bone. The osteocyte itself, by its fine structure and relationship to the intralacunar matrix seems to be engaged not only in the maintenance of the open pathways in bone but also in the transport mechanism itself.This investigation was carried out under the auspices of the United States Atomic Energy Commission and was supported, in part, by research career program award 5-K3-DE 7, 272 and research grants De-01406 and DE-01716 from the National Institute of Dental Research, National Institutes of Health, Bethesda, Maryland.     

Stain Technology: Use of Tannic Acid for the Ultrastructural Visualization of Periplasm in Gram-Negative Bacteria

Tannic acid mordanting reveals the periplasm, the area between the outer membrane and the inner membrane of gram-negative bacteria, Rhizobium gp., Escherichia colt and Enterobacter aeregenes, as an electron-dense layer continuous with the inner leaflet of the outer membrane. The method involves 18 hr of tannic acid treatment after fixation in aldehyde prior to osmium tetroxide postfixation, followed by conventional electron microscopy.     

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.     

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.     

Investigations into the structure and fixation properties of cytoplasmic lamellae in the hamster oocyte

Summary Lamellar structures have been revealed in the cytoplasm of rapidly growing hamster oocytes by glutaraldehyde fixation and by fixation in 30% ethanol followed by osmication. The structures are not preserved after osmium tetroxide either used alone or followed by glutaraldehyde; nor are they preserved by absolute ethanol, formaldehyde, glyceraldehyde, glyoxal, 2-hydroxy-adipaldehyde or potassium permanganate. Immersion in 30% ethanol followed by extraction in distilled water and fixation in glutaraldehyde and osmium tetroxide exposes the lattice-like skeletal structure of the lamellae. The lamellae are present but slightly altered after short digestion in pepsin. Longer digestion results in complete dissolution of the structures.Supported by U.S.P.H.S. Post-doctoral Fellowship 5 F2 HD-25, 190–02.I wish to thank Prof. R. E. Coupland for his continued interest in this work and for his helpful criticisms.     

Effect of collidine (2,4,6-trimethylpyridine) on the osmiophilia and chromaffin reaction in the synaptic vesicles of rat pineal nerves

Rat pineal nerve endings contain a population of small and of large synaptic vesicles that are either electron lucent or have electron-dense cores. It has been reported that their osmiophilia is eliminated when collidine buffer is used in the fixation procedure. We investigated this effect and found that osmium tetroxide and potassium dichromate reactivity were abolished when excised pineal glands were briefly incubated with collidine buffer before glutaraldehyde-cacodylate fixation. Such an effect was not observed when collidine was applied after fixation. Glands that had been fixed in glutaraldehyde or osmium tetroxide buffered with collidine exhibited a peripheral zone containing reactive synaptic vesicles and a deeper, central zone where such reactivity was absent. These results indicate that the effect of collidine is due to depletion of monoamines rather than to chemical blockage of their reactivity, and further suggest that collidine has a higher rate of penetration into tissues than the tested fixatives.     

An ultrastructural study of the interaction of liposomes with plant protoplasts

A one-step procedure using a mixture of glutaraldehyde and osmium tetroxide was devised to fix in situ large unilamellar liposomes of phosphatidylserine for transmission electron microscopy (TEM), since the conventional fixation method was found to be inadequate in this respect. The new fixation procedure enabled us to visualize the sequence of events in the interaction of liposomes with protoplasts from Vinca rosea suspension cultures in the presence of polyethylene glycol. Liposomes were thus found adhering to the surface of protoplasts, in association with invaginating plasmalemma, and within intracellular vesicles. These observations showed that liposomes enter plant protoplasts via endocytosis. Ultrastructural profiles indicating fusion of liposomes with protoplasts were not observed.     

Swelling of golgi apparatus cisternae in monensin-treated tissues is modulated by fixation conditions

Summary Swelling of Golgi apparatus cisternae is reported to be a common response to the ionophore, monensin. However, the amount of swelling depends on fixation, thus raising the question of whether the swelling response is due to monensin or to the fixation protocol. To resolve this problem, maize root cap cells were treated with monensin and then fixed with glutaraldehyde and osmium tetroxide (applied sequentially), osmium tetroxide alone, or aqueous potassium permanganate, or were quick frozen in liquid propane and substituted in acetone-osmium tetroxide. The chemical fixatives (which take minutes to stabilize tissue elements) were judged by comparison with freeze substitution which requires only fractions of a second to stabilize tissue elements. The results verify that monensin causes cisternal swelling and that this swelling is best observed at the ultrastructural level by fixation in glutaraldehyde/osmium tetroxide or by freeze substitution.     

A note on some non-membranous structures in plant mitochondria

Summary Electron-opaque inclusions, seen in the mitochondrial matrix of several plant tissues after glutaraldehyde and osmium tetroxide fixation, with uranyl acetate and lead citrate poststaining, are described. Some tentative proposals about their composition and function are put forward.     

Parathyroid hormone promotes cartilage healing after free reduction of mandibular condylar fractures by upregulating Sox9

After high fractures of the mandibular condyle, the insufficient blood supply to the condyle often leads to poor bone and cartilage repair ability and poor clinical outcome. Parathyroid hormone (PTH) can promote the bone formation and mineralization of mandibular fracture, but its effects on cartilage healing after the free reduction and internal fixation of high fractures of the mandibular condyle are unknown. In this study, a rabbit model of free reduction and internal fixation of high fractures of the mandibular condyle was established, and the effects and mechanisms of PTH on condylar cartilage healing were explored. Forty-eight specific-pathogen-free (SPF) grade rabbits were randomly divided into two groups. In the experimental group, PTH was injected subcutaneously at 20 µg/kg (PTH (1–34)) every other day, and in the control group, PTH was replaced with 1 ml saline. The healing cartilages were assessed at postoperative days 7, 14, 21, and 28. Observation of gross specimens, hematoxylin eosin staining and Safranin O/fast green staining found that every-other-day subcutaneous injection of PTH at 20 µg/kg promoted healing of condylar cartilage and subchondral osteogenesis in the fracture site. Immunohistochemistry and polymerase chain reaction showed that PTH significantly upregulated the chondrogenic genes Sox9 and Col2a1 in the cartilage fracture site within 7–21 postoperative days in the experimental group than those in the control group, while it downregulated the cartilage inflammation gene matrix metalloproteinase-13 and chondrocyte terminal differentiation gene ColX. In summary, exogenous PTH can stimulate the formation of cartilage matrix by triggering Sox9 expression at the early stage of cartilage healing, and it provides a potential therapeutic protocol for high fractures of the mandibular condyle.