Actin filament destruction by osmium tetroxide

We have studied the destruction of purified muscle actin filaments by osmium tetroxide (OsO4) to develop methods to preserve actin filaments during preparation for electron microscopy. Actin filaments are fragmented during exposure to OsO4. This causes the viscosity of solutions of actin filaments to decrease, ultimately to zero, and provides a convenient quantitative assay to analyze the reaction. The rate of filament destruction is determined by the OsO4 concentration, temperature, buffer type and concentration, and pH. Filament destruction is minimized by treatment with a low concentration of OsO4 in sodium phosphate buffer, pH 6.0, at 0 degrees C. Under these conditions, the viscosity of actin filament solutions is stable and actin filaments retain their straight, unbranched structure, even after dehydration and embedding. Under more severe conditions, the straight actin filaments are converted into what look like the microfilament networks commonly observed in cells fixed with OsO4. Destruction of actin filaments can be inhibited by binding tropomyosin to the actin. Cross-linking the actin molecules within a filament with glutaraldehyde does not prevent their destruction by OsO4. The viscosity decrease requires the continued presence of free OsO4. During the time of the viscosity change, OsO4 is reduced and the sulfur-containing amino acids of actin are oxidized, but little of the osmium is bound to the actin. Over a much longer time span, the actin molecules are split into discrete peptides.     

Tissue fixation and osmium black formation with nonvolatile octavalent osmium compounds.

Several compounds of osmiumVIII, including potassium osmiamate and coordination complexes of OsO4 with ammonia and various heterocyclic nitrogen compounds, have been synthesized and characterized. They have also been evaluated as substitutes for OsO4 in postfixation of biological specimens and in light and electron microscopic cytochemical methods resulting in osmium black formation. The most useful of these osmic compounds, a molecular addition complex of hexamethylenetetramine (methenamine) with OsO4, has a negligible vapor pressure of OsO4. It has the molecular formula C6H12N4.2OsO4 and has been designated osmeth. Although it has only limited solubility, aqueous solutions of the compound (or of OsO4) can be rapidly prepared by dissolution in a minimal amount of dimethylformamide and subsequent dilution with distilled water or buffer. Although stable in the solid state, the complex in solution undergoes partial dissociation releasing OsO4, and the odor of OsO4 becomes apparent. Such solutions of osmeth are (approximately 0.25%) considerably less concentrated with respect to OsO4 than solutions (1-2%) ordinarily employed for ultrastructural preservation or in cytochemical studies. Osmeth has limited value for postosmication after glutaraldehyde fixation because the generation (release) of OsO4 appears to be slow. Adequate osmication of tissue blocks exists only at the surface, but effective osmication can be achieved throughout tissue sections. In cytochemical reactions resulting in the formation of osmium blacks, the osmeth solutions are as effective as OsO4 solutions of equivalent concentrations. Our findings indicate that OsO4 solutions of less than 1% may be satisfactorily utilized in many cytochemical studies. Osmeth is safer and more convenient to handle than OsO4 because small amounts may be solubilized as needed. It should be considered as a substitute for OsO4 in ultrastructural cytochemistry. These results suggest that the effectiveness of OsO4 as a fixative may, in part, be related to its nonpolarity.The infrared spectra indicate that the OsO4 molecule is tetrahedral, perfectly symmetrical and, therefore, as a whole nonpolar. As a consequence, it could be expected to readily penetrate charged surfaces of tissues, cells, and organelles. The spectral studies show that osmeth is much less symmetrical and, to that extent, polar; thus, it penetrates biomembranes less readily.     

Osmium tetroxide: a new probe for site-specific distortions in supercoiled DNAs.

Supercoiled plasmids Col E1 and cDm 506 (a Col E1 derivative carrying the D. melanogaster histone gene repeat) were treated with OsO4 in presence of pyridine and the reaction products were analyzed using different approaches. Gel electrophoresis showed that OsO4 binding to supercoiled DNA induced its relaxation without nicking. The amount of osmium bound to DNA (as determined electrochemically) increased with the extent of DNA relaxation. As a result of osmium modification of supercoiled cDm 506, a single denaturation "bubble" was observed in the electron microscope. Mapping of the osmium binding site by S1 nuclease cleavage followed by restriction enzyme digestion has revealed one major site in the intergenic spacer between the H1 and H3 histone genes of D. melanogaster. This site differs from the site cleaved by S1 nuclease in supercoiled DNA in the absence of osmium.     

Increase in the calcium content of cardiac tissue after postfixation with osmium tetroxide

The concentration of osmium has been measured by destructive chemical analysis in glutaraldehyde fixed heart tissue postfixed with osmium tetroxide and embedded in epoxy resin. After such treatment, the mean atomic number of the specimen (Z) is close to 10, which permits a quantitative analysis of calcium (Ca) by the continuum method, using Z2/A as a correcting factor (A: atomic weight). Wavelength-dispersive X-ray microanalysis has been used to determine the Ca concentration of frog cardiac tissue fixed in glutaraldehyde and embedded in resin. These measurements have been repeated on tissue postfixed in osmium tetroxide; contrary to expectations, the apparent Ca concentration is much higher in osmium treated than in nontreated tissue. However, this result is observed with OsO4 solutions prepared in glass, not with solutions prepared in plastic. It is shown by energy dispersive X-ray analysis of droplets that OsO4 solutions prepared in glass contain large amounts of calcium, potassium and silicon. Care must be taken in preparing OsO4 fixatives when the fixed tissues are to be subjected to X-ray microanalysis of such elements as Ca or Si.     

Effects of fixatives on function of pulmonary surfactant.

The structure of pulmonary surfactant films remains ill defined. Although plausible film fragments have been imaged by electron microscopy, questions about the significance of the findings and even about the true fixability of surfactant films by the usual fixatives glutaraldehyde (GA), osmium tetroxide (OsO(4)), and uranyl acetate (UA) have not been settled. We exposed functioning natural surfactant films to fixatives within a captive bubble surfactometer and analyzed the effect of fixatives on surfactant function. The capacity of surfactant to reach near-zero minimum surface tension on film compression was barely impaired after exposure to GA or OsO(4). Although neither GA nor OsO(4) prevented the surfactant from forming a surface active film, GA increased the equilibrium surface tension to above 30 mN/m, and both GA and OsO(4) decreased film stability as seen in the slowly rising minimum surface tension from 1 to ~5 mN/m in 10 min. In contrast, the effect of UA seriously impaired surface activity in that both adsorption and minimum surface tension were substantially increased. In conclusion, the fixatives tested in this study are not suitable to fix, i.e., to solidify, surfactant films. Evidently, however, OsO(4) and UA may serve as staining agents.     

The zinc iodide-osmium tetroxide staining-fixative of Maillet. Nature of the precipitate studied by x-ray microanalysis and detection of Ca2+-affinity subcellular sites in a tonic smooth muscle.

A mechanism of osmium reduction during zinc iodide-osmium tetroxide (ZIO) fixation is proposed. X-ray powder microanalyses of ZIO precipitates formed both in the presence or absence of tissues are identical with those of CuOsO4 and CuRuO4. Therefore, and based on indexation methods, ZnOsO4 was found to be the formula of the ZIO mixture reduction; this zinc osmate has an orthorhombic crystalline lattice. In smooth muscle preparations, ZIO electron dense deposits are localized in both cisternae of the sarcoplasmic reticulum and in mitochondria after a short fixation time. According to the microanalysis results, the zinc osmate has been associated to Ca2+ high affinity sites since Zn2+ is either replacing Ca2+ and/or displacing it by having a higher affinity for Ca2+ binding sites. Consequently, the ZIO mixture might be useful in revealing some Ca2+ storage sites in cells. This hypothesis was tested in ABRM preparations by selectively depleting sites which are known to bind Ca2+. In this case, the sarcoplasmic reticulum only retains the staining deposits after a short ZIO fixation. It is likely that OsO4 alone, used as fixative in cytology might be due to the formation of metallic osmates (e.g., divalent osmates like CaOsO4). In addition, of course, reduction of osmium during tissue fixation is accompanied by oxidation of double bonds of lipoproteic complexes or unsaturated lipids, and oxidation of sulfhydryl groups and amino groups.     

Observations on the kinetics of uranyl acetate and phosphotungstic acid staining of chromatin in thin sections for electron microscopy

When thin sections of spermatogenic chromatin are fixed with either glutaraldehyde alone or postfixed with osmium tetroxide (OsO4) and stained with uranyl acetate (UAc) for increasing times, even after as little as 1 min, stain uptake is proportional to section thickness. Greater UAc uptake is observed in chromatin fixed with glutaraldehyde only, but seen with postfixed chromatin. Lead citrate poststaining of chromatin fixed with either glutaraldehyde or postfixed with OsO4 increases UAc uptake by a factor of about 3. The staining of thin sections of spermatogenic chromatin with ethanolic phosphotungstic acid (PTA) shows a region where stain uptake is proportional to section thickness followed by a plateau. This staining pattern is seen in chromatin fixed with glutaraldehyde alone or postfixed with OsO4; similar levels for final PTA uptake are also observed. An increase in the resin content of embedded chromatin postfixed with OsO4 is proposed to explain the decrease and increase in the rate of migration of UAc and ethanolic PTA staining solutions, respectively.     

Electron microscopic characterization of calcium-binding physodes in the green alga Mougeotia scalaris.

Effect of the covalently cross-linking agents glutardialdehyde and osmium tetroxide, and of adsorption of the vital dye, neutral red, to the matrix of the calcium-binding "vesicles" from the green alga Mougeotia scalaris has been analysed in situ, both in terms of structural preservation and of the calcium-binding capacity of the vesicles. Upon cell fixation in glutardialdehyde without OsO4, the vesicles appear to dissolve, but upon simultaneous fixation in glutardialdehyde with OsO4 (1% w/v), the vesicles retain a globular form, are evenly stained by osmium and appear to be surrounded by a membrane-like structure. This structure was also observed around the vesicles in cells preincubated for 10 min in 0.1 mM neutral red and then fixed in glutardialdehyde/OsO4 for 1 h. More detailed information of the matrix structure is obtained when simultaneous fixation of the Mougeotia cells was shortened to 15 min: a membrane-like structure was no longer observed around the vesicles. After cell treatment in the presence of neutral red, no calcium at all was found inside the vesicles. A small amount of calcium remained, when cells were fixed simultaneously and extensively in the absence of neutral red. However, calcium was found, to a considerable extent, inside the vesicles after short simultaneous fixation of the cells in the absence of neutral red. Based on the ultrastructural and elemental features presented here, the calcium-binding vesicles in Mougeotia appear to represent a member of the large family of (calcium-binding) physodes in lower plants (CaBP).     

The reactions of oxo-osmium ligand complexes with isopentenyl adenine and its nucleoside.

We report syntheses of oxo-osmium(VI)bis(ligand) esters of N6-(delta2-isopentenyl) adenine (6-ipAde) and its nucleoside (IPA) which result from the addition of OsO4 to the double bond of the isopentenyl group. A study of the kinetics of these reactions shows that under typical conditions the rates of reaction relative to thymidine are as follows: for OsO4-pyridine: thymidine = 1; 6-ipAde = 4600: for OsO4-2,2'-bipyridyl: thymidine = 380; 6-ipAde = 8600; IPA = 8600. We also report syntheses of osmate esters of IPA in which the osmium is bonded through the 2'-and 3'-hydroxyl groups of the ribose residue.     

A practical technique to postfix nanogold-immunolabeled specimens with osmium and to embed them in Epon for electron microscopy.

Nanogold is a tiny gold probe, freely diffusible in cells and tissues, and is suitable for pre-embedding immunohistochemistry. However, it is necessary to develop Nanogold to a larger size so that it can be observed by conventional transmission electron microscopy. Silver enhancement is usually used for visualizing Nanogold, but the silver shell produced is unstable in OsO(4) and often becomes invisible after OsO(4) postfixation, which is necessary for good visualization of ultrastructure. We used silver enhancement with silver acetate, followed by gold toning with chloroauric acid, to replace the silver shell with a more stable gold in order to observe Nanogold after osmium fixation and Epon embedding. This technique is applicable to various intra- and extracellular antigens. For correlative observation of immunolabled specimens by light and electron microscopy, specimens adhered to slideglasses were embedded in Epon under non-adhesive plastic film. By heating the Epon sheets after polymerization, these supports were removed without difficulty and provided easy correlative observation.     

Oxidative damage in DNA. Lack of mutagenicity by thymine glycol lesions

Thymine glycol (5,6-dihydroxy-5,6-dihydrothymine) is a base damage common to oxidative mutagens and the major stable radiolysis product of thymine in DNA. We assessed the mutagenic potential of thymine glycols in single-stranded bacteriophage DNA during transfection of Escherichia coli wild-type and umuC strains. cis-Thymine glycols were induced in DNA by reaction with the chemical oxidant, osmium tetroxide (OsO4); modification of thymines was quantitated by using anti-thymine glycol antibody. Inactivation of transfecting molecules showed that one lethal hit corresponded to 1.5 to 2.1 thymine glycols per phage DNA in normal cells, whereas conditions of W-reactivation (SOS induction) reversed 60 to 80% of inactivating events. Forward mutations in the lacI and lacZ' (alpha) genes of f1 and M13 hybrid phage DNAs were induced in OsO4-treated DNA in a dose-dependent manner, in both wild-type and umuC cells. Sequence analysis of hybrid phage mutants revealed that mutations occurred preferentially at cytosine sites rather than thymine sites, indicating that thymine glycols were not the principal pre-mutagenic lesions in the single-stranded DNA. A mutagenic specificity for C----T transitions was confirmed by OsO4-induced reversion of mutant lac phage. Pathways for mutagenesis at derivatives of oxidized cytosine are discussed.     

A chemical mechanism for tissue staining by osmium tetroxide-ferrocyanide mixtures.

The presence of Fe(CN)6(-4) provides sequential, one-electron reduction pathways for OSO4. An equilibrium is established containing OSO4, Fe(CN)6(-4), Fe(CN)6(-3), OSO2(OH)4(-4), and labile cyano-bridged OS-Fe species containing Os in nominal oxidation states of VIII, VII, and VI. These osmium complexes are chelated by appropriately placed donor atoms in the macromolecular tissue matrix, and chelation facilitates the reduction of osmium in situ to lower oxidation states (predominantly IV) that are relatively nonlabile. The greater reactivity and concentration of the Os(VII and VI) intermediates in this system leads to more Os deposition than OsO4 alone; the chelation is responsible for the immobilization of Os and the observed staining pattern in electron micrographs. Chemical data from model systems and electron micrographs of tissue are presented in support of this mechanism.     

Tissue fixation and staining by osmium tetraoxide: a possible role for alkaloids

In vitro studies on the reactions of osmium tetraoxide, OsO4, with isoquinoline, pyridine, quinuclidine, and a series of structurally related alkaloids suggest that these species, under the conditions of normal tissue staining and fixation, are potentially osmiophilic. The structure of the products and their reactions with unsaturated substrates are described. The relevance of these results to the process of tissue staining and fixation of plant tissues containing alkaloids by OsO4 is discussed.     

Sequence dependence for bypass of thymine glycols in DNA by DNA polymerase I.

Single-stranded phage DNAs containing thymine glycols were prepared by oxidation with osmium tetroxide (OsO4) and were used as templates for DNA synthesis by E. coli DNA polymerase I. The induction of thymine glycol lesions in DNA, as measured by immunoassay, quantitatively accounted for an inhibition of in vitro DNA synthesis on modified templates. Analysis of termination sites for synthesis by DNA polymerase I (Klenow fragment) showed that DNA synthesis terminated at most template thymine sites in OsO4-treated DNA, indicating that incorporation occurred opposite putative thymine glycols in DNA. Nucleotides 5' and 3' to putative thymine glycol sites affect the reaction, however, since termination was not observed at thymines in the sequence 5'-CTPur-3'. Conversion of thymine glycols to urea residues in DNA by alkali treatment caused termination of DNA synthesis one nucleotide 3' to template thymine sites, including thymines in the 5'-CTPur-3' sequence, showing that the effect of surrounding sequence is on the elongation reaction by DNA polymerase rather than differential damage induction by OsO4.     

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

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.     

The use of osmium-thiocarbohydrazide-osmium (OTO) and ferrocyanide-reduced osmium methods to enhance membrane contrast and preservation in cultured cells

The preservation and contrast of membranous structures in cultured cells using various postfixation procedures prior to embedding have been investigated. These include routine OsO4, ferrocyanide-reduced OsO4, osmium-thiocarbohydrazide-osmium (OTO), and ferrocyanide-reduced osmium-thiocarbohydrazide-ferrocyanide-reduced osmium (R-OTO). With standard ethanol-Epon dehydration/embedding techniques, a dramatic improvement in both membrane contrast and preservation of bilayer membrane structure was achieved using preembedding OTO in cultured cells. R-OTO yielded similar enhanced preservation and contrast of membranes. Both of these methods also resulted in an increase in the contrast of diaminobenzidine reaction product from horseradish peroxidase activity, and of lipid droplets and lipoprotein particles. However, R-OTO did not cause the same increase in the density of proteinaceous elements as was seen with the OTO method. Ferrocyanide-reduced osmium alone showed significant advantages for quantitation of immunocytochemistry using ferritin labels with bismuth subnitrate counterstain. These methods should have general usefulness for the preservation of lipid-containing structures in cultured cells.     

An electron microscope study of myelin figures

In the electron microscope, thin sections of OsO(4)-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 OsO(4) 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 OsO(4) in it.     

Prolonged osmification as an indicator of the differentiation process in the endomembrane system.

The technique of prolonged osmification was used in the analysis of reducing capacity of perinuclear space, endoplasmic reticulum and cis-Golgi cisternae in different epithelial cells during embryonic differentiation and immediately after the birth. Cells of the mouse gastric and intestinal epithelium and of the exocrine pancreas and mammary gland were analyzed. It was shown that endomembrane compartments exhibit high variability in their capacity to reduce OsO4 into lower valency oxides. Typical staining of cis-Golgi cisternae by osmium black does not occur before the cells achieve the developmental state in which production of specific products starts. The changes in stainability occurring from the perinuclear space and endoplasmic reticulum towards the cis-Golgi cisternae indicate a maturation pathway with no direct correlation to the chemical characteristic of the substances produced in different cell types. In the mammary gland the reduction capacity of endoplasmic reticulum disappeared with the intensive synthesis of lipids. Considering our previous results and those of other authors, the possible reasons for the observed dynamics in reducibility in particular segments of endomembraneous space are discussed.     

PRESERVATION OF MYELIN LAMELLAR STRUCTURE IN THE ABSENCE OF LIPID : A Correlated Chemical and Morphological Study

The fine structure of myelin was studied in glutaraldehyde-fixed rat sciatic nerves depleted of lipid by acetone, chloroform:methanol (2:1 v/v), and chloroform:methanol:concentrated HCl (200:100:1, v/v/v). One portion of each of these nerves, plus the extracts, was saponified and analyzed by gas-liquid chromatography for fatty acids. The remainder of each nerve was stained in osmium tetroxide in CCl₄ (5g/100cc) and was embedded in Epon 812. Thin sections, examined in the electron microscope, revealed the preservation of myelin lamellar structure with a 170 A periodicity in nerves depleted of 98% of their lipids. Preservation of myelin lamellar structure depended on glutaraldehyde fixation and the introduction of osmium tetroxide in a nonpolar vehicle (CCl₄) after the lipids had been extracted. It is concluded that the periodic lamellar structure in electron micrographs of myelin depleted of lipid results from the complexing of osmium tetroxide, plus uranyl and lead stains, with protein.     

Osmium tetroxide, used in the treatment of arthritic joints, is a fast mimic of superoxide dismutase

Aqueous solutions of osmium tetroxide (OsO4) have been injected into arthritic knees for the past 45 years to chemically destroy diseased tissue, in a procedure termed "chemical synovectomy." Arthritis is an inflammatory disease. The primary inflammatory chemical species are the superoxide anion radical (O2.-) and nitric oxide (.NO), which combine to form the peroxynitrite anion (ONOO-). Here we show that OsO4 does not react with ONOO- but very efficiently catalyzes the dismutation of O2.- to O2 and H2O2. Using the pulse-radiolysis technique, the catalytic rate constant has been determined to be (1.43+/-0.04) x 10(9) M-1 s-1, independent of the pH in the 5.1-8.7 range. This value is about half that for the natural Cu,Zn-superoxide dismutase (Cu,Zn-SOD). Per unit mass, OsO4 is about 60 times more active than Cu,Zn-SOD. The catalytically active couple is OsVIII/OsVII, OsVIII oxidizing O2.- to O2 with a bimolecular rate constant of k=(2.6+/-0.1)x10(9) M-1 s-1 and OsVII reducing it to H2O2 with a bimolecular rate constant of (1.0+/-0.1)x10(9) M-1 s-1. Although lower valent osmium species are intrinsically poor catalysts, they are activated through oxidation by O2.- to the catalytic OsVIII/OsVII redox couple. The OsVIII/OsVII catalyst is stable to biochemicals other than proteins and peptides comprising histidine, cysteine, and dithiols.