potassium-permanganate and uranyl-acetate

For wool, superior staining of a wide range of ultrastructural components is achieved by en bloc treatment of fibres with a chemical reductant followed by osmium tetroxide. For human scalp hair, although staining quality is similar, the penetration of reagents is poor, resulting in large parts of the fibre cortex remaining unstained. Here we describe a modification to the reduction-osmication method in which reagents penetrate through a cut fibre end, allowing visualization of a wide range of features across the cortex. We compare the staining quality, artefacts and range of structure rendered visible using transmission electron microscopy for en bloc reduction-osmication to other staining alternatives including en bloc silver nitrate and section stains based on uranyl acetate and lead citrate, phosphotungstic acid, potassium permanganate, ammoniacal silver nitrate and some combinations of these stains. The effects of hair-care treatments are briefly examined.

Topics: Coloring Agents; Female; Hair; Hair Preparations; Histological Techniques; Humans; Lead; Microscopy, Electron, Transmission; Organometallic Compounds; Osmium Tetroxide; Oxidation-Reduction; Phosphotungstic Acid; Potassium Permanganate; Silver; Silver Nitrate; Staining and Labeling

Electron staining reagents were examined to find a possible substitute for uranyl acetate (UA) in electron microscopy of bacterial ultrathin sections. Four kinds of stains, platinum blue (Pt-blue), oolong tea extract (OTE), potassium permanganate (KMnO(4)) and phosphotungstic acid (PTA), were examined in comparison with UA either with or without post-staining with lead citrate (Pb). Electron microscopy was performed on sections from Spurr-embedded cells of a Gram-positive bacterium, Bacillus cereus NBRC 13597, and a Gram-negative bacterium, Escherichia coli NBRC 3301. Both Pt-blue and OTE showed staining similar to each other and to that of double staining with UA and Pb in B. cereus, while in E. coli the cytoplasmic membrane appeared less dense when compared with UA and Pb. KMnO(4) stained excessively to some extent, but showed images of the best contrast in the cytoplasmic membrane comparable with UA and Pb among the four reagents. PTA could stain the peptidoglycan layer but gave images of low quality for both bacteria. This study demonstrated that none of the reagents examined showed staining results of the same quality or better than the conventional method with UA and Pb. However, stains of Pt-blue, OTE and KMnO(4) could possibly be an alternative candidate for the UA according to the structure in question.

Topics: Bacillus cereus; Electrons; Escherichia coli; Freeze Substitution; Lead; Microscopy, Electron; Microtomy; Organometallic Compounds; Phosphotungstic Acid; Platinum; Potassium Permanganate; Staining and Labeling; Tissue Embedding

The high-pressure freezing/freeze substitution technique followed by Lowicryl K4M embedding provided an excellent ultrastructure and retention of antigenicity of rat gastric glands as well as the intraluminal fluid contents. By taking this advantage, we histochemically investigated the excretory flow of the zymogenic and mucin contents in rat gastric glandular lumen at the ultrastructural level. The combination of KMnO(4)-UA/Pb staining for zymogenic contents and Griffonia simplicifolia agglutinin-II (GSA-II) labeling for mucous neck cell (MNC) mucin distinguished the exocytosed zymogenic contents from the MNC mucin in the glandular lumen. Interestingly, at the base and neck regions, the zymogenic contents showed a droplet-like appearance, forming a distinct interface with the MNC mucin. At the pit region, the GSA-II labeling demonstrated restricted paths, designated as MNC mucous channels, which flowed into the surface mucous gel layer. It should be noted that the interface between exocytosed zymogenic contents and MNC mucin disappeared, and that the zymogenic contents merged into the MNC mucous channels. At the top pit region, the surface mucous gel layer showed laminated arrays of three types of gastric mucins. On the basis of these ultrastructural findings, we propose a model of the excretory flow in rat gastric gland.

Topics: Animals; Enzyme Precursors; Freeze Substitution; Frozen Sections; Gastric Mucosa; Immunohistochemistry; Lead; Male; Mucins; Organometallic Compounds; Potassium Permanganate; Rats; Rats, Wistar; Staining and Labeling

A simple contrast enhancement method is presented for Lowicryl K4M ultrathin sections prepared by high pressure freezing/freeze substitution. The sections were treated with an acidified potassium permanganate oxidizing solution followed by uranyl acetate and lead citrate staining. The method, designated KMnO4-UA/Pb staining, provided a much greater contrast in electron microscopy than conventional UA/Pb staining. In detail, the visibility of plasma membrane was especially improved and the nuclear heterochromatin, mitochondria and cytoplasmic ribosomes showed an adequate increase in electron density. In the mucous cells of rat Brunner's glands, the Golgi cisternae were well defined with the KMnO4-UA/Pb staining. Interestingly, the membranes of the intermediate compartments were moderately reactive to the KMnO4-UA/Pb staining, whereas the cis and the trans compartments were only faintly stained. It should be emphasized that the KMnO4 oxidation following colloidal gold labelling did not cause a remarkable reduction of immunogold labelling and the enhanced contrast helped us to examine the gold particles with high accuracy. This contrast enhancement method is highly promising, with the potential to become a useful tool for histochemical investigation, including immunocytochemistry with the Lowicryl K4M ultrathin sections prepared by high pressure freezing/freeze substitution techniques.

Topics: Acrylic Resins; Animals; Citric Acid; Duodenum; Electron Probe Microanalysis; Epithelial Cells; Freezing; Histocytochemistry; Image Enhancement; Jejunum; Lead; Microscopy, Electron; Organometallic Compounds; Oxidation-Reduction; Potassium Permanganate; Pressure; Rats; Rats, Wistar; Staining and Labeling; Stomach; Tissue Embedding

High-pressure freezing/freeze substitution followed by Lowicryl K4M embedding provided an excellent morphology and antigenicity of the gastric glands, as well as the intraluminal fluid contents. Taking advantage of this, we histochemically investigated the secretory dynamics of the zymogenic contents in rat gastric gland, with special references to phospholipase A(2) (PLA(2)) and phospholipase Cgamma1 (PLCgamma1). The combination of immunogold labeling and KMnO4-uranyl acetate-lead citrate staining for zymogenic contents clearly demonstrated the rapid diffusion of PLA(2) molecules from the exocytosed zymogenic contents into the mucinous contents in gastric glandular lumens. In contrast, the exocytosed PLCgamma1 molecules remained within the zymogenic contents in the glandular lumens. These findings indicated the distinction between the exocytosed PLA(2) and PLCgamma1 in their diffusion rate. In addition, the mucinous contents surrounding the exocytosed zymogenic contents were intensely labeled with Griffonia simplicifolia II lectin which specifically recognizes the mucin of mucous neck cells. Interestingly, some of the PLA(2) immunolabeling on the mucinous contents was associated with the apical membranes of gastric epithelial cells, especially that of parietal cells. The secretory dynamics of the zymogenic contents in rat gastric glands, including their interaction with the mucinous contents are discussed.

Topics: Acrylic Resins; Animals; Enzyme Precursors; Exocytosis; Freeze Substitution; Freezing; Gastric Mucosa; Immunohistochemistry; Isoenzymes; Lead; Male; Microscopy, Electron; Organometallic Compounds; Phospholipase C gamma; Phospholipases A; Potassium Permanganate; Pressure; Rats; Rats, Wistar; Staining and Labeling; Type C Phospholipases

The high pressure freezing/freeze substitution technique is known to yield a deep vitreous freezing of tissues. Combination of this technique with Lowicryl K4M embedding allows us histochemical studies of dynamic cellular processes with improved structural preservation. The disadvantage of Lowicryl K4M embedding is its poor electron density in electron microscopy. To address this problem, we examined the effects of KMnO4 oxidation applied to Lowicryl K4M embedded rat gastric glands processed by high pressure freezing. The KMnO4 oxidation-uranyl acetate-lead citrate sequence succeeded not only in contrast enhancement of cellular components, but also in differential staining of the zymogen granules of rat gastric chief cells. This technique could be applied to semi-thin sections of Lowicryl K4M embedded rat gastric glands. The KMnO4 oxidation-toluidine blue staining provided sufficient contrast with regard to the zymogen granules. Various experiments used in this study verified that the KMnO4 oxidation plays an essential role in the differential staining of the zymogen granules. Combined use of the KMnO4 oxidation with phospholipase A2-immunostaining demonstrated that gold labeling was localized to the zymogen granules without the loss of immunolabeling. Energy dispersive X-ray microanalysis revealed some manganese depositions on the zymogen granules. It is highly anticipated that the KMnO4 oxidation will become a useful tool for histochemical investigations combined with cryofixation/freeze substitution and low temperature embedding techniques.

Topics: Acrylic Resins; Animals; Chief Cells, Gastric; Citrates; Coloring Agents; Cytoplasmic Granules; Electron Probe Microanalysis; Enzyme Precursors; Fixatives; Freeze Substitution; Lead; Male; Microscopy, Electron; Organometallic Compounds; Oxidation-Reduction; Phospholipases A; Phospholipases A2; Potassium Permanganate; Pressure; Rats; Rats, Wistar; Staining and Labeling; Tissue Embedding