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

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

Osmium-labeled polysaccharides for atomic microscopy

With the objective of localizing cell surface polysaccharides, the reaction of several osmium (VI)-ligand complexes with glycols has been applied to sugar residues in mono- and polysaccharides. The hydrophilic ligands 4,4′-dicarboxy-2,2′-bipyridine and N,N,N′,N′-tetramethylethylenediamine have been employed to produce water-soluble osmate esters of the sugar glycols. Methyl glycosides react with osmium (VI) reagents to give stable products containing one osmium atom per sugar. α-Cyclodextrins, with six glucose residues in a ring, and β-cyclodextrins with seven, can bind up to, but not exceeding three osmium ligand complexes per molecule, indicating possible nearest-neighbor exclusion of reaction among the residues. Reaction of as little as 1% of the sugar residues in amylose with the dicarboxybipyridyl osmate complex allows the amylose strands to be extended on a grid for electron microscopy. Further reaction with the tetramethylethylenediamine osmate complex rapidly saturates the amylose to a level of 0.39 osmium atom per sugar residue, consistent with the nearest-neighbor exclusion hypothesis. High resolution scanning transmission electron microscopy images reveal a row of osmium atoms along each amylose strand.     

Osmium-labeled polynucleotides. Incorporation of additional heavy atoms (mercury) via ligand substitution reactions

The reaction of osmium tetroxide with biological materials, particularly nucleic acids, has considerable utility in electron microscopy and X-ray crystallography. This heavymetal label introduces an electrophilic center which may serve as a means of attachment of nucleophiles. Nucleophilic ligand substitution reactions have been exploited as a means of adding more heavy metals (mercury) onto the osmium label. Furthermore, the technique is quite general and could be used to modify the osmium label with, for example, fluorescent groups. The nucleophilic exchange reactions have also been studied using ¹H nmr spectroscopy with a representative heterocyclic osmate ester derivative, the bis(pyridine) osmate ester derivative of TMP. These studies have defined the nature of the ligands which lead to stable osmium labels.     

Osmium (VI) complexes of the 3', 5'-dinucleoside monophosphates, ApU and UpA.

The dinucleoside monophosphates, ApU and UpA, react with potassium osmate (VI) and 2,2'-bipyridyl to form the corresponding oxo-osmium (VI) bipyridyl sugar ester in which the osmate group is bonded to the terminal 2',3'-glycol. Osmium (VIII) tetroxide and 2,2'-bipyridyl react with the dinucleosides to form the corresponding oxo-osmium (VI) bipyridyl heterocyclic esters which result from addition of the tetroxide to the 5,6-double bond of the uracil residue. Although capable of transesterification reactions, these heterocyclic esters are exceptionally stable toward exchange reactions in solution. No apparent exchange was observed after 1 month. This reaction thus seems promising for single-site osmium labeling in polynucleotides.     

Electron microscopic demonstration of rat liver glycogen phosphorylase activity with iron (Fe++)

Summary In this study a new electron microscopic method for the demonstration of liver glycogen phosphorylase activity has been presented.Prior to incubation the liver samples were shortly fixed in cold paraformaldehyde. Inorganic phosphate, liberated in the reaction catalyzed by the enzyme, were precipitated with iron (Fe⁺⁺) present in the incubating medium. Postfixation was performed in glutaraldehyde and osmium tetroxide.The ferrous phosphate precipitate was detected electron microscopically in unstained sections.The precipitate was mainly localized to endoplasmic membranes but also in glycogen particles. The method is imperfect in demonstrating phosphorylase activity bound to glycogen particles because of poor preservation of glycogen during treatment.     

The chemical nature of osmium tetroxide fixation and staining of membranes by X-ray photoelectron spectroscopy

X-ray photoelectron spectroscopy was used to determine the oxidation states of osmium compounds present in erythrocyte ghost preparations and related systems treated with osmium tetroxide. Osmium tetroxide and cholesterol, codeposited at ?100 °C, began to react at ?70 °C, and Os(VI) was formed. Similarly, Os(VI) was detected for the known cholesterol-osmate ester prepared and purified chemically. However, osmium tetroxide applied in phosphate buffer (pH 7.2) gave rise to large proportions of Os(IV) and Os(III) species in addition to Os(VI) compounds. Egg phosphatidylcholine likewise produced a mixture of Os(VI), Os(IV), and Os(III), but dipalmitoyl phosphatidylcholine failed to give significant amounts of osmium containing products under identical conditions. Glutaraldehyde gave a mixture of compounds with the same osmium oxidation states when allowed to react with aqueous osmium tetroxide. Unfixed and glutaraldehyde-fixed erythrocyte ghosts also produced mixtures of Os(VI), Os(IV) and Os(III) under conditions identical to those of normal tissue processing. Additionally, the mixture of adducts initially formed by treatment with osmium tetroxide was further reduced by dehydration of the tissue with ethanol, resulting in a final mixture which was 50–60% Os(III).The results support a scheme for the reaction of osmium tetroxide with tissues in which the initial reaction site is the double bonds of unsaturated lipids to form Os(VI) derivatives. Subsequent hydrolysis and further reduction yield complexes of Os(IV) and Os(III). A mixture of these three states is present in membrane specimens during microscopic observation. Os(VI) and Os(IV) could be present as osmate esters and osmium dioxide, respectively; Os(III) could be present as an oxo- or amino complex(es). The photoelectron spectrum of intact erythrocyte ghosts can be synthesized from the spectra of phospholipid and cholesterol only, suggesting the predominance of the reaction with lipids in the fixation process.     

The chemical nature of osmium tetroxide fixation and staining of membranes by x-ray photoelectron spectroscopy.

X-ray photoelectron spectroscopy was used to determine the oxidation states of osmium compounds present in erythrocyte ghost preparations and related systems treated with osmium tetroxide. Osmium tetroxide and cholesterol, codeposited at -100 degrees C, began to react at -70 degrees C, and Os(VI) was formed. Similarly, Os(VI) was detected for the known cholesterol-osmate ester prepared and purified chemically. However, osmium tetroxide applied in phosphate buffer (pH 7.2) gave rise to large proportions of Os(IV) and Os(III) species in addition to Os(VI) compounds. Egg phosphatidylcholine likewise produced a mixture of Os(VI), Os(IV), and Os(III), but dipalmitoyl phosphatidylcholine failed to give significant amounts of osmium containing products under identical conditions. Glutaraldehyde gave a mixture of compounds with the same osmium oxidation states when allowed to react with aqueous osmium tetroxide. Unfixed and glutaraldehyde-fixed erythrocyte ghosts also produced mixtures of Ss(VI), Os(IV) and Os(III) under conditions identical to those of normal tissue processing. Additionally, the mixture of adducts initially formed by treatment with osmium tetroxide was further reduced by dehydration of the tissue with ethanol, rpesulting in a final mixture which was 50-60% Os(III). The results support a scheme for the reaction os osmium tetroxide with tissues in which the initial reaction site is the double bonds of unsaturated lipids to form Os(VI) derivatives. Subsequent hydrolysis and further reduction yield complexes of Os(IV) and Os(III). A mixture of these three states is present in membrane specimens during microscopic observation. Os(VI) and Os(IV) could be present as osmate esters and osmium dioxide, respectively; Os(III) could be present as an oxo- or amino complex(es). The photoelectron spectrum of intact erythrocyte ghosts can be synthesized from the spectra of phospholipid and cholesterol only, suggesting the predominance of the reaction with lipids in the fixation process.     

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.     

The specific cytochemical demonstration in the electron microscope of periodate-reactive mucosubstances and polysaccharides containing vic-glycol groups

Summary A technique is described for the localization in the electron microscope of periodate-reactive mucosubstances and polysaccharides containing vic-glycol groups. In this technique the sugar residues are oxidized by periodic acid and the resulting aldehydes condensed with pentafluorophenylhydrazine under specified conditions. Further increase in specific electron density is achieved by treating the hydrazone end-product with ammonium sulphide followed by osmium tetroxide to form an osmium black.The technique has been applied to liver and small intestine cells in which glycogen, sialomucins and sulphated mucosubstances reacted especially strongly. A marked positive reaction has also been obtained from the interstitial cell matrix and from the Golgi apparatus and multivesicular bodies of the intestinal epithelial cells.The reaction can be prevented by the omission of the periodate oxidation and, if due to glycogen, by prior treatment with diastase.     

Periodic acid Schiff--p phenylenediamine staining of glycogen in chondrocytes. A new combination which improves both cellular detail and glycogen identification

This study reports a method whereby glycogen is identified in the chondrocytes of the secondary center of ossification prior to mineralization. The use of new fuchsin rather than basic fuchsin on one micron Spurr sections of femoral head cartilage fixed with potassium ferrocyanide-reduced osmium produced excellent identification of glycogen and when followed by p phenylenediamine, intensified cellular detail.     

Demonstration of intracytoplasmic glycogen of megakaryocytes and blood platelets by means of the periodic acid-thiocarbohydrazide-silver proteinate method

Summary The glycogen of megakaryocytes and blood platelets has been investigated in glutaraldehyde and osmium tetroxide fixed tissues by the periodic acid-thiocarbohydrazide-silver proteinate method (PA-TCH-SP). The PA-TCH-SP method involves the staining of intracytoplasmic glycogens more densely than the routine lead citrate method. Glycogen having a mean particle diameter of 21.1 nm has been shown localizing in the matrix of mature megakaryocytes, while that of glycogen in the platelets was 26.2 nm. The staining pattern of the glycogen in blood platelets was classified into three groups according to staining intensity.It is found that the PA-TCH-SP method is a very suitable one for the demonstration of intracytoplasmic glycogen from the viewpoints of reaction specificity, reproducibility, fineness of reaction products, sufficiency of electron density, and experimental cost. This method is also a very useful one for differentiating intracytoplasmic glycogens and ribosomes.     

Demonstration of intracytoplasmic glycogen of megakaryocytes and blood platelets by means of the periodic acid-thiocarbohydrazide-silver proteinate method.

The glycogen of megakaryocytes and blood platelets has been investigated in glutaraldehyde and osmium tetroxide fixed tissues by the periodic acid-thiocarbohydrozide-silver proteinate method (PA-TCH-SP). The PA-TCH-SP method involves the staining of intracytoplasmic glycogens more densely than the routine lead citrate method. Glycogen having a mean particle diameter of 21.1 nm has been shown localizing in the matrix of mature megakaryocytes, while that of glycogen in the platelets was 26.2 nm. The staining pattern of the glycogen in blood platelets was classified into three groups according to staining intensity. It is found that the PA-TCH-SP method is a very suitable one for the demonstration of intracytoplasmic glycogen from the viewpoints of reaction specificity, reproducibility, fineness of reaction products, sufficiency of electron density, and experimental cost. This method is also a very useful one for differentiating intracytoplasmic glycogens and ribosomes.     

Periodic acid Schiff-p phenylenediamine staining of glycogen in chondrocytes

Summary This study reports a method whereby glycogen is identified in the chondrocytes of the secondary center of ossification prior to mineralization. The use of new fuchsin rather than basic fuchsin on one micron Spurr sections of femoral head cartilage fixed with potassium ferrocyanide-reduced osmium produced excellent identification of glycogen and when followed by p phenylenediamine, intensified cellular detail.     

The Ultrastructure of Chlorobium tepidum Chlorosomes Revealed by Electron Microscopy

Chlorosomes are the light harvesting structures of green photosynthetic bacteria. Each chlorosome from green sulfur bacteria houses hundreds of thousands of bacteriochlorophyll molecules in addition to smaller amounts of chlorobiumquinone and carotenoids. In electron microscopy studies, chlorosomes exhibit different appearances depending on the fixation method used. Fixation with osmium tetroxide results in electron-transparent chlorosomes. Fixation with potassium permanganate results in clearly delineated electron-dense chlorosomes. This fixation method features an electron-transparent area in the interior of the chlorosome. In addition to electron density patterns that can be considered compositions of rod-shaped elements, chlorosomes exhibit a striation pattern that is oriented parallel to the longitudinal axis. Treatment with osmium tetroxide followed by potassium permanganate treatment results in a more diffused density distribution that outlines connecting elements between the chlorosome and the cytoplasmic membrane, and connecting elements between the cytoplasmic membrane and the outer membrane, which act as a diffusion barrier for electron density.     

A quantitative immunoperoxidase procedure employing energy dispersive x-ray analysis.

A method is described for substituting gold for osmium as a marker in the unlabeled antibody technique. The gold marker can be detected in the light or electron microscope. The gold-labeled reaction product can be detected in lower concentrations than osmium and can be used as the basis for quantitating antigen concentrations in cells and tissues with the scanning electron microscope and energy dispersive x-ray analysis.     

X-ray microanalysis of aldehyde-fixed glycogen contrast-stained by OsVI . FeII and OsVI . RuIV complexes

The composition of the contrast-donating complex of rat liver glycogen, nucleoplasm, erythrocytes, and mitochondria was established by X-ray microanalysis. In these compartments the presence of osmium and iron was shown qualitatively in tissue after glutaraldehyde fixation, treated with OsVIIIO4 plus K4FeII(CN)6 and in similar tissue treated with a combination of K2OsVIO4 plus K4FeII(CN)6. Osmium and ruthenium were detected in these compartments, in aldehyde-fixed tissue treated with mixtures containing K2RuIVL(CN)6 rather than K4FeII(CN)6. The iron detected in the glycogen, nucleoplasm, erythrocytes, and mitochondria of tissue treated with K2RuIV(CN)6 mixtures proved to derive from sources inside the electron microscope, and had to be considered an artifact. Quantitatively, the mean atomic ratios of osmium-to-iron and osmium-to-ruthenium were determined from spectra obtained by point analyses of the same compartments (glycogen, nucleoplasm, mitochondria, lipid droplets, and erythrocytes). After correction of the spectra for the instrumental iron contribution, the osmium-to-iron and osmium-to-ruthenium ratios in the glycogen were about 1:3 for tissue treated with those combinations including K2OsVIO4. In the other compartments, the osmium-to-iron and osmium-to-ruthenium ratios were virtually 1:0. For Os-VIIIO4 in combination with potassium ferrouscyanide however the osmium-to-iron ratio was 1:7 in the glycogen and 1:5 in all other compartments. OsVIIIO4 was combined with potassium ruthenium-cyanide, the osmium-to-ruthenium ratio was 1:2 in the glycogen and 2:1 in the other compartments. These results support our view that the selective glycogen contrast is obtained by complex formation.     

Ultrastructural cytochemistry of the secretory granules of the hamster submandibular gland

Summary The ultrastructure and cytochemistry of the secretory granules of the male hamster submandibular salivary gland were studied. After fixation in glutaraldehyde followed by osmium tetroxide the granules exhibit a characteristic bipartite substructure, with an electron lucid crescenteric rim and a more dense central core. A differentiation into two regions of the granules could also be visualized in specimens primarily fixed in Millonig's osmium tetroxide or in potassium permanganate. The electron lucid peripheral portion of the membrane bounded secretory granules further displays a strong positive reaction after staining of ultrathin sections with the periodic acid-chromic acid-(PA-CrA)-silver technique. The strong periodate reactivity of the rim relative to the core, suggests a difference in mucin composition of the two granule regions. With the PA-CrA-silver staining technique a positive reaction was also observed within the Golgi apparatus of the acinar cells.     

Studies of Osmium Deposits in the Carotid Body of the Cat

Double aldehyde fixed carotid bodies and small pieces of vagus nerve of cats were incubated in 3 mM copper sulfate and 0.5 mM potassium ferricyanide in 0.05 M acetate buffer (pH 5.6) for 30 minutes at room temperature. Several modifications of this procedure were also attempted. Tissues were then postosmicated with 2% unbuffered osmium tetroxide and heated to 50-55 C for ten minutes. Under the electron microscope carotid body cells exhibited fine osmium deposits within cisternae of endoplasmic reticulum, saccule and vesicles of Golgi complex, and cristae of mitochondria. Intense osmium precipitation was also noted in the mitochondria of nerve endings. In addition, much more intense, more conspicuous and more localized reaction wan noted in the intraperiod lines of the myelin sheath of nerves. Deposits here were rod-shaped, displaying considerable variation in length. These results are discussed in the light of previous findings on osmium deposits in various tissues. It was concluded that the osmium reaction is unspecific, and that histochemical methods employing hot osmium tetroxide to amplify enzymatic activities may therefore not be reliable.     

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.     

The Use of Osmium Tetroxide-Potassium Ferrocyanide as an Extracellular Tracer in Electron Microscopy

Secondary treatment of glutaraldehyde fixed liver samples with long term stored solutions of osmium tetroxide and potassium ferrocyanide (Os-Fe) results in tracing of the extracellular spaces of the tissue with an electron opaque substance. This substance does not diffuse across cell membranes, its formation probably being related to the progressive reduction of the O_sO₄ molecule by potassium ferrocyanide. The application of the present method in electron microscopy may be useful in overcoming the artifacts often induced by other tracing techniques such as vascular perfusion with peroxidase or immersion in lanthanum. Although the period of storage of the Os-Fe solution is a clear disadvantage of the method, it seems plausible to anticipate that further studies on the chemical interaction between osmium tetroxide and potassium ferrocyanide will provide us with a Os-Fe mixture having an immediate tracer effect.