Nile blue A as a fluorescent stain for poly-beta-hydroxybutyrate

Poly-beta-hydroxybutyrate granules exhibited a strong orange fluorescence when stained with Nile blue A. Heat-fixed cells were treated with 1% Nile blue A for 10 min and were observed at an excitation wavelength of 460 nm. Glycogen and polyphosphate did not stain. Nile blue A appears to be a more specific stain for poly-beta-hydroxybutyrate than Sudan black B.     

Nile red: a selective fluorescent stain for intracellular lipid droplets

We report that the dye nile red, 9-diethylamino-5H-benzo[alpha]phenoxazine-5-one, is an excellent vital stain for the detection of intracellular lipid droplets by fluorescence microscopy and flow cytofluorometry. The specificity of the dye for lipid droplets was assessed on cultured aortic smooth muscle cells and on cultured peritoneal macrophages that were incubated with acetylated low density lipoprotein to induce cytoplasmic lipid overloading. Better selectivity for cytoplasmic lipid droplets was obtained when the cells were viewed for yellow-gold fluorescence (excitation, 450-500 nm; emission, greater than 528 nm) rather than red fluorescence (excitation, 515-560 nm; emission, greater than 590 nm). Nile red-stained, lipid droplet-filled macrophages exhibited greater fluorescence intensity than did nile red-stained control macrophages, and the two cell populations could be differentiated and analyzed by flow cytofluorometry. Such analyses could be performed with either yellow-gold or red fluorescence, but when few lipid droplets per cell were present, the yellow-gold fluorescence was more discriminating. Nile red exhibits properties of a near-ideal lysochrome. It is strongly fluorescent, but only in the presence of a hydrophobic environment. The dye is very soluble in the lipids it is intended to show, and it does not interact with any tissue constituent except by solution. Nile red can be applied to cells in an aqueous medium, and it does not dissolve the lipids it is supposed to reveal.     

Pyronin Y as a fluorescent stain for paraffin sections

Pyronin Y has long been used, in combination with other dyes such as Methyl Green, as a differential stain for nucleic acids in paraffin tissue sections. It also forms fluorescent complexes with double-stranded nucleic acids, especially RNA, enabling semi-quantitative analysis of cellular RNA in flow cytometry. However, the possibility of using pyronin Y as a fluorescent stain for paraffin tissue sections has rarely been investigated. We herein report that in sections stained with Methyl Green–pyronin Y, red blood cells, elastic fibre of blood vessels, zymogen granules of pancreatic acinar cells, surface membrane of heptocytes and kidney tubular cells showed strikingly strong green and/or red fluorescence, while the nuclei of cells appeared non-fluorescent. The use of confocal laser-scanning microscope greatly improved the resolution and selectivity of the fluorescent images. Staining with pyronin Y alone gave similar results in terms of fluorescence properties of the specimens. Pretreatment of paraffin sections with RNase significantly reduced cytoplasmic pyronin Y staining as judged by transmission light microscopy, but it had little effect on the fluorescence intensity of red blood cells, elastic fibres and zymogenbreak granules.     

An investigation of hydroethidine as a fluorescent vital stain for prokaryotes

Abstract Hydroethidine (HE), manufactured by the chemical reduction of ethidium bromide (EB), was found to be decomposed to a bright red-fluorescent product by a range of microorganisms. Therefore, HE seemed to have potential as a fluorescent vital stain for microorganisms. However, inhibited or killed bacterial cultures still fluoresced red. Short periods (2–4 min) of excitation of sterile solutions of HE with a UV light yielded an orange/red product. Thus, HE seems to be decomposed biologically by a number of microorganisms but also abiotically by UV light-mediated process to red fluorescent material. These observations suggest that the oxidation of HE has only limited potential for assessing microbial activity.     

Victoria blue B--a nuclear stain for cytology. A cytophotometric study

The aim of this study was to investigate the staining characteristics of Victoria Blue B in alcohol solutions. Cytological specimens (liver and spleen tissue imprints, blood smears) were stained with methanol solutions of commercially available Victoria Blue B-Cl and with pure Victoria Blue B-BF4. The dye concentration, staining time, and protone concentration of the dye solution were varied. The dye solutions were characterized using spectrophotometry and thin-layer chromatography. Cytophotometry and image analysis were used to quantitate the staining pattern of cell nuclei. Feulgen-stained slides were used as controls. Victoria Blue B-BF4 gave excellent nuclear staining exhibiting a quantitative dye-substrate relationship, whereas commercial dyes resulted in lower staining intensity and less distinct nuclear texture. Dye concentration and staining time were, over wide ranges, not of critical importance for the quality of the staining. Under certain staining conditions, only cell nuclei were stained, with the background remaining completely unstained. We presume that, in alcohol solutions, Victoria Blue dye binds as a neutral dye molecule in conjunction with its anion. Victoria Blue B-BF4 staining provides a simple and reproducible staining technique for cytology which is suitable for use in automated cell-pattern recognition.     

Victoria blue B — a nuclear stain for cytology

Summary The aim of this study was to investigate the staining characteristics of Victoria Blue B in alcohol solutions. Cytological specimens (liver and spleen tissue imprints, blood smears) were stained with methanol solutions of commercially available Victoria Blue B-Cl and with pure Victoria Blue B-BF₄. The dye concentration, staining time, and protone concentration of the dye solution were varied. The dye solutions were characterized using spectrophotometry and thin-layer chromatography. Cytophotometry and image analysis were used to quantitate the staining pattern of cell nuclei. Feulgen-stained slides were used as controls. Victoria Blue B-BF₄ gave excellent nuclear staining exhibiting a quantitative dye-substrate relationship, whereas commercial dyes resulted in lower staining intensity and less distinct nuclear texture. Dye concentration and staining time were, over wide ranges, not of critical importance for the quality of the staining. Under certain staining conditions, only cell nuclei were stained, with the background remaining completely unstained. We presume that, in alcohol solutions, Victoria Blue dye binds as a neutral dye molecule in conjunction with its anion. Victoria Blue B-BF₄ staining provides a simple and reproducible staining technique for cytology which is suitable for use in automated cell-pattern recognition.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthdayThis study was supported by a grant from the Bundesministerium für Forschung und Technologie, Bonn-Bad Godesberg, Federal Republic of Germany, (no. 01 Z08501/6)     

Nile red as a polarity-sensitive fluorescent probe of hydrophobic protein surfaces

Nile red is an uncharged hydrophobic molecule whose fluorescence is strongly influenced by the polarity of its environment. It interacts with many, but not all, native proteins, including beta-lactoglobulin, kappa-casein, and albumin, with a wide range of spectral changes for different proteins. It detects the exposure or formation of new hydrophobic surfaces induced by ligand binding to calmodulin, oligomerization of melittin, or unfolding of ovalbumin during early thermal denaturation. The dye is photostable, the working wavelength range is broad and removed from those at which many biomolecules absorb, the fluorescence is unaffected by pH between 4.5 and 8.5, the quantum yield is high, and hydrophobic sites on proteins may be investigated in dilute solutions.     

A combined fluorescent and electron microscopic stain for elastic tissue

Synopsis A histochemical procedure for fluorescent and electron microscopic observations of elastic tissue has been developed. This was accomplished by combining thein vivo andin vitro staining properties of non-metallic tetraphenylporphine sulphonate and its silver derivative. The non-metallic porphyrin gives a bright red fluorescence to elastica after injection, but it does not make the tissue electron dense. However, the metallic derivative imparts a specific electron density to elastica afterin vitro staining, but it does not render elastica either fluorescent or electron dense after injection. Thus, elastic tissue can be viewed with the fluorescence microscope after injection of the nonmetallic porphyrin. Sections from the same block can be stainedin vitro with silver tetraphenylporphine sulphonate and observed in the electron microscope. The nonmetallic porphyrin readily crosses the placental barrier and, therefore, can be used to study the elastica in foetuses by fluorescence microscopy.