Cytochemical Method to Localize Acidic Nuclear Proteins

Fast green FCF was used to localize acidic nuclear proteins in sections of young flower buds of Limnophyton obtusifolium (L.) Miq. After extracting nucleic acids, the slides were stained at hydrogen ion concentrations ranging from pH 2.6 to 9.0. At pH 5.0 and 8.0 staining is confined to the nucleus with no cytoplasmic reaction. Staining intensity is greater at pH 5.0 than at pH 8.0. The proteins responding to fast green at pH 8.0 are basic proteins. The positive reaction at pH 5.0 is attributed to acidic nuclear proteins. These findings are confirmed by control preparations. Acetylated slides and slides treated with 0.25 N HCl were unstained at pH 8.0 but staining at pH 5.0 was undisturbed. Dilute alkali (0.003 N NaOH) reduced staining intensity at pH 5.0 but had no effect at pH 8.0. Methylated slides did not stain at pH 5.0, but at pH 8.0 staining was unaffected. Deamination blocked staining at both pH's. It is concluded that fast green at pH 5.0 specifically binds with acidic nuclear proteins.     

Studies and critique of Amido Black 10B, Coomassie Blue R, and Fast Green FCF as stains for proteins after polyacrylamide gel electrophoresis.

The properties of amido black 10B (C.I. 20470), Coomassie blue R (C.I. 42660), and fast green FCF (C.I. 42053) as protein stains, along with a few comments on Coomassie blue G (C.I. 42655), are presented and dye impurities and their effects on protein-dye binding within gels are discussed. All three dyes produced metachromatic effects with some proteins. Problems encountered with long-term stability and fixation of certain maize seed proteins are reported along with procedures for overcoming them. The low solubility of Coomassie blue R in trichloroacetic acid prevented maximum staining and destaining within a reasonable time, whereas other solvents allowed diffusion of some proteins during staining. Coomassie blue R binds to proteins in much higher amounts than do amido black and fast green, which accounts for its sensitivity in detection of protein bands in gels. Procedures for obtaining maximum contrast with photographs are also outlined.     

Quantitation of protein on gels and blots by infrared fluorescence of Coomassie blue and Fast Green

Coomassie blue staining of gels and blots is commonly employed for detection and quantitation of proteins by densitometry. We found that Coomassie blue or Fast Green FCF bound to protein fluoresces in the near infrared. We took advantage of this property to develop a rapid and sensitive method for detection and quantitation of proteins in gels and on blots. The fluorescence response is quantitative for protein content between 10 ng and 20 microg per band or spot. Staining and destaining require only 30 min, and the method is compatible with subsequent immunodetection.     

Staining Bacteria and Yeasts with Acid Dyes

Various acid dyes prove satisfactory for the routine staining of bacteria. Those used are acid fuchsin, anilin blue w. s., fast acid blue R, fast green FCF, light green, orseilline BB, erythrosin, phloxine and rose bengal. Acid fuchsin, fast green, anilin blue, and orseilline are especially recommended. Phenolic solutions of the dyes, acidified with acetic acid, with the addition of ferric chloride to those containing acid fuchsin, anilin blue, fast green or light green, are used. Procedures are given in detail for staining or demonstrating vegetative cells, resting and germinating spores, capsules, sheaths and glycogen in bacteria; germinating and conjugating spores of yeast; and for counterstaining after acid fast or Gram staining. The principal advantages of using acid dyes are better differentiation, and less tendency for slime amd debris to take the dye.     

Discrepancies between cytophotometric alkaline Fast Green measurements and nuclear histone protein content

Synopsis Nuclei of different cell types of the myelopoietic series from normal human bone marrow smears were stained with Fast Green FCF, and their dye uptake estimated by cytophotometry. In very immature cell types (myeloblasts and promyelocytes), a high percentage of nuclei either did not stain, or had a dye content too low to be measured. Fast Green absorbencies were increased in the more mature stages. The highest values occurred in mature polymophonuclear leukocytes. The varying Fast Green absorbancies in the nuclei of different cell types suggest that the staining capacity of histone proteins depends on the functional state of the chromatin and does not indicate variations in the histone content of the nuclei.     

An innovative brilliant blue FCF method for fluorescent staining of fungi and bacteria

Abstract

Most natural and synthetic dyes currently used for microbial fluorescent staining are toxic or carcinogenic and are harmful to animals, humans and the environment. A food dye for microbial staining, brilliant blue FCF, was used as an alternative to lactofuchsin and lactophenol blue. Brilliant blue FCF shows pronounced microbial cell fluorescence staining of an array of pathogenic/toxigenic (Fusarium granunearum 3- and 15-acetyldeoxynivalenol chemotypes, and Escherichia coli O157:H7) and beneficial fungi and bacteria (Trichoderma harzianum and Bacillus subtilis). Brilliant blue FCF has no toxic effects on the microbes tested and is inexpensive.     

Staining protein in isoelectric focusing gels with fast green

A rapid, simple technique for staining proteins in isoelectric focusing polyacrylamide gels was demonstrated using fast green in 10% acetic acid. Fast green has the distinct advantage of not binding to ampholytes, thus staining only protein. Maximum staining was achieved within 5 min, and bands were visible after 3 to 6 h of destaining. Background stain removal, however, was not complete until 72 h after placing gels in a diffusion destainer. Gel quantitation was demonstrated with actin using fast green and Coomassie brilliant blue R-250. A standard curve prepared with fast green was linear from 0.5 to 8 μg of actin in contrast to Coomassie brilliant blue R-250 which provided linearity from 0.1 to 2.5 μg actin. Application of fast green staining to quantitation of α-actin from cultured muscle satellite cells has been demonstrated.     

A note on the demonstration of nuclear acidic HCl insoluble proteins in peripheral blood smears.

The present study deals with the conditions necessary for the specific demonstration of nuclear acidic HCl insoluble proteins is smeared peripheral leucocytes by means of a simple cytochemical procedures. These proteins can be very easily selectively demonstrated by staining with Azure C or Toluidine blue above pH 6, after the fixation of smears with methanol, extraction of histones, nucleic acids (with HCl, TCA) and treatment with formaldehyde. The double fixation with methanol and formaldehyde facilitated specific extraction of nuclear acidic HCl insoluble proteins of smeared leucocytes with pepsin. The nuclear acidic HCl insoluble proteins are present in leucocytes in interchromatin areas and their isoelectric point determined by cytochemical procedure is pH 6.     

Staining Mitochondria in Saccharomyces cerevisiae

After testing various procedures (amidoblack 10B, acid fuchsin-methyl blue, Luxol fast blue MBS-phloxine, toluidine blue O, Jams green B and pinacyanol), three stains can be recommended for staining both types of mitochondria (globose and threadlike) in the cells of Saccharomyces cerevisiae: (1) 0.1% solution of amidoblack 10B in citrate buffer (pH 3.0) for 10 min; (2) 0.01% solution of toluidine blue O in phosphate buffer (pH 6.0) for 30 min; (3) 0.01% solution of Janus green B in distilled water (pH 5.6) for 30 min. The latter stain is most specific because its staining reaction depends upon the action of the mitochondrial enzyme cytochrome c oxidase. Yet, low concentrations and short incubation periods must be applied to avoid poisoning of the cell metabolism.     

Methods for the Standardization of Biological Stains: Part IV

In this paper are given methods for determining the suitability of certain dyes of the triphenylmethane group for certification by the Commission on Standardization of Biological Stains. These methods have been developed by the Commission, in cooperation with the Color and Farm Waste Division, Bureau of Chemistry and Soils, U. S. Department of Agriculture. The dyes for which the methods are given in the present paper are: Malachite green, brilliant green, light green SF yellowish, fast green FCF, basic fuchsin (rosanilin and pararosanilin), acid fuchsia, methyl violet, crystal violet, gentian violet, methyl green and anilin blue. For each of these dyes, methods are discussed under the following headings: (1) identification or qualitative examination; (2) quantitative analysis; and (3) biological tests.     

An Evaluation of the Metachromasy of Anionic Dyes. I. Visual Observations on Tissue Sections

Thirteen dyes of the azo (benzopurpurin, Congo red, trypan blue, chromotrope 2R, orange G), indigoid (indigocarmine), triphenylmethane (acid fuchsin, aniline blue, light green, methyl blue), and xanthene (eosin B, eosin Y, erythrosin B) groups were applied under standard conditions to a variety of human, rabbit, rat, mouse and frog tissues in paraffin sections. Sections were examined for color changes which might indicate metachromatic reactions analogous to the metachromasy of cationic dyes. Disazo and xanthene dyes showed shifts in hue, with some qualification on the shifts of xanthenes. Metachromatic shifts of anionic dyes were generally of low order compared to those of cationic dyes. Nuclei, erythrocytes, inner elastic laminae of arteries, keratinous structures, and certain areas in the ground substance of connective tissue most often elicited metachromasy. It is suggested that basic proteins are responsible for the metachromatic reactions. Equally interesting areas were those staining poorly (cartilage matrix, most types of mucus), since these are sites of highly acidic substances capable of binding proteins.     

An Eosin-Fast Green-Naphthol Yellow Mixture for Differential Staining of Cytologic Components in Mammalian Permatozoa

Air-dried smears of saline suspensions of mammalian spermatozoa were stained for 10-60 min at room temperature in a mixture of eosin Y, fast green FCF, and naphthol yellow S (0.1% w/v, each dye) in 1.0% aqueous acetic acid. They were then blotted, rinsed in 1.0% acetic acid until no more dye was removed (0.5-1.5 min), blotted and allowed to dry completely, rinsed in xylene and mounted in synthetic resin. In all species examined except the rat, acrosomes were stained greenish blue to bluish green or blue depending on their thickness; in the rat, they displayed more affinity for eosin and were reddish. In all species, spermatozoan nuclei were strongly stained by naphthol yellow. In intact sperm heads, postnuclear cap had a yellowish green appearance. Midpieces of rodent spermatozoa, especially those of younger gametes, were stained bright red while those of ejaculated bull and rabbit spermatozoa were stained blue-green. Cytoplasmic droplets associated with rodent spermatozoa were consistently stained a dark green. In all species, the remainder of the flagellum generally was stained bluish to blue-black. Deductions concerning the morphology of spermatozoa derived from the staining experiments were verified by means of scanning electron microscopy. Because it provides reliable information concerning the morphology of the various components of mammalian spermatozoa, this simple staining procedure should prove applicable to a wide variety of studies involving the morphology of intact spermatozoa     

Staining Chromosomes in Sections of Germinal Vesicles of Sarcoptid Mites by a Schiff Reagent

Chromosomes of oocytes, especially early prophase I stages, of Acaridae and Anoetidae species are difficult to stain by procedures using hematoxylin, Feulgen and aceto-orcein. Hematoxylin stains are intensely polychromatic in oocytes; the standard Feulgen procedure is negative with chromosomes during diffuse prophase stages. Satisfactory staining can be obtained with a supersensitive Schiff reagent (Tobie, W. C., Ind. Eng. Chem., Anal. Ed., 14: 405—406, 1942) made by reducing basic fuchsin with gaseous SO₂. Routinely prepared paraffin sections of mites fixed in Carnoy's 6:3:1 mixture were hydrolysed 5-8 min in 1 N HCl, washed well, and stained in this reagent: 1-2 hr for prophase oocytes, 10-20 min for condensed chromosomes. A second staining in a 0.5% aqueous solution of toluidine blue 0, adjusted to pH 5.3-5.5 with a citrate buffer, served to darken the original Feulgen stain. Counterstaining with 0.1-0.2% fast green FCF in the last fluid of the dehydrating series enhanced contrast between chromosomes and cytoplasm. This staining technic is also suitable for preparing whole mounts of mites.     

Arginine-rich proteins in spherical inclusions of human locus coeruleus neurons demonstrated by benzil modification

Previous studies have shown that aminergic neurons in the normal human brain contain acidophilic cytoplasmic inclusions--called protein bodies (PBs)--that are reduced or absent in parkinsonism and disrupted in depression. The purpose of the present study was to elucidate the constitution of PBs in five formalin-fixed normal human brains using histochemical methods specific for histones, protamines, and the amino acid arginine. PBs were revealed with alkaline fast green and bromphenol blue, exhibiting a high content in histones and in protamines. They developed blue metachromasia with phosphotungstic acid-hematoxylin and green fluorescence with phenanthrenequinone, which established the presence of arginyl residues. Using benzil, which selectively modifies the guanido group of arginine, staining was blocked for each of the above two methods. The application of Mallory's trichrome procedure after benzil differentiated the PBs into an unstained core and a still fuchsinophilic rim. Since the fuchsinophilia of the rim was shown to persist after acetylation as well, we suggest that this rim probably contains acidic macromolecules that attach to the basic charges of the amphoteric acid fuchsin. We conclude that the PB are complex structures consisting of a core segregating arginine-rich proteins and a rim which probably contains macromolecules of an acidic nature.     

A Tetrachrome Stain for Fresh, Mineralized Bone Sections, Useful in the Diagnosis of Bone Diseases

Fresh, unprocessed bone is ground to sections 75-100 μ thick, stained in an aqueous solution composed of fast green FCF, 0.1 gm; orange G, 2.0 gm; distilled water, 100.0 ml; and adjusted to pH 6.65, then in a mixture of 1 part alcoholic solution of 0.25% celestine blue B and 9 parts of alcoholic solution of 0.1% basic fuchsin. Surface stain is removed by grinding sections to 50 μ and washing them in 1% invert soap (Zephiran) to remove adherent debris. (Commercial detergents and alkaline soaps may interfere with chromophore groups of the dyes.) Wash in tap water; rinse in distilled water and differentiate in 1% acetic alcohol. Dehydrate in ascending alcohols, clear in xylene and mount permanently in a neutral, synthetic resin. Active osteoid seams stain dark to light green; resting osteoid seams, red to bright orange red; transitional osteoid seams, geenish-yellow, orange red to red; older, partly mineralized matrix, orange; new, partly mineralized matrix, red; osteocyte nuclei, red; osteoblasts and osteoclasts, greenish-blue to dark purple nuclei and green or light green cytoplasm. Hyper-trophic and differentiating cartilage cells are stained light pink and dark red respectively. The staining reactions are consistent; the solutions are stable.     

A Modification of the Technic of Handling Chick Embryos

In this paper are given methods for determining the suitability of certain dyes of the triphenylmethane group for certification by the Commission on Standardization of Biological Stains. These methods have been developed by the Commission, in cooperation with the Color and Farm Waste Division, Bureau of Chemistry and Soils, U. S. Department of Agriculture. The dyes for which the methods are given in the present paper are: Malachite green, brilliant green, light green SF yellowish, fast green FCF, basic fuchsin (rosanilin and pararosanilin), acid fuchsia, methyl violet, crystal violet, gentian violet, methyl green and anilin blue. For each of these dyes, methods are discussed under the following headings: (1) identification or qualitative examination; (2) quantitative analysis; and (3) biological tests.     

New tetrachromic VOF stain (Type III-G.S) for normal and pathological fish tissues

A new VOF Type III-G.S stain was applied to histological sections of different organs and tissues of healthy and pathological larvae, juvenile and adult fish species (Solea senegalensis; Sparus aurata; Diplodus sargo; Pagrus auriga; Argyrosomus regius and Halobatrachus didactylus). In comparison to the original Gutiérrez VOF stain, more acid dyes of contrasting colours and polychromatic/metachromatic properties were incorporated as essential constituents of the tetrachromic VOF stain. This facilitates the selective staining of different basic tissues and improves the morphological analysis of histochemical approaches of the cell components. The VOF Type III -6.5 stain is composed of a mixture of several dyes of varying size and molecular weight (Orange G相似文献   

Enzymatic, isoelectric, and molecular-weight characterization of water-soluble maize-pollen proteins

Maize (Zea mays L. cv. Kansas Drought Synthetic) pollen proteins were fractionated via a continuous tandem cascade ultrafiltration system into three molecular-weight classes. Proteins from the whole extract and each fraction were further separated by polyacrylamide gel electrofocusing in the pH 5 to 9 range and characterized by their enzymatic activity and isoelectric point. Twenty-one protein bands were detected with Fast Green FCF staining. Esterase, peroxidase, leucine aminopeptidase, catalase, and amylase activities were located in 16 bands. Five bands remained unclassified. All the enzymes assayed, except amylase, were polymorphic. The extractions, fractionations and zymograms were reproducible and indicated that several protein bands contained at least two different enzymes with very similar molecular weight class and isoelectric point for each enzyme and protein band     

On the Structure and Staining of Starch Grains of the Potato Tuber

Procedures are described for the differential staining of starch grains of the potato tuber with hematoxylin, and for double staining with safranin 0 and fast green FCF. The staining effects obtained are made possible by the action of a swelling agent. Staining with hematoxylin is preceded by the swelling action of formaldehyde. In staining with safranin 0 and fast green FCF, the formaldehyde is added to the staining solution. The results obtained are as follows: (1) a clavate-shaped, central structure composed of small particles arranged in definite layers is revealed within the grain; (2) differential staining of the locus of the grain and the lamellae alternating with it in a small region around the longitudinal axis of the grain; (3) the simultaneous staining and separation of the grain into a cone-shaped peripheral portion and a spherical body containing the locus of the grain which emerges from it; and (4) differential staining of a ring or layer of substance around a spherical refractive body within the grain.     

Enrichment of the basic/cationic urinary proteome using ion exchange chromatography and batch adsorption

Anionic or acidic proteins are the main compositions of normal urinary proteome. Efforts to characterize human urinary proteome, thus, have focused mainly on the anionic compartment. The information of cationic or basic proteins present in the normal urine is virtually unknown. In the present study, we applied different methods to enrich cationic urinary proteome. Efficacies of these methods were compared using equal volume (1 L) of urine samples from the same pool obtained from 8 normal healthy individuals. Cation exchange chromatography using RESOURCE-S column provided the least amount of the recovered proteins, whereas batch adsorption using SP Sepharose 4 Fast Flow beads equilibrated with acetic acid (pH 4.8) provided the greatest yield of protein recovery. The recovered proteins were then resolved with 2-DE (pI 7-11) and identified by peptide mass fingerprinting using MALDI-TOF MS. There were several isoforms of immunoglobulin heavy and light chains enriched by these methods. In addition, three isoforms of interferon alpha-3 (IFNalpha3) and six isoforms of eosinophil-derived neurotoxin (EDN), were also enriched. The enrichment of IFNalpha3 and EDN was particularly effective by batch adsorption using SP Sepharose 4 Fast Flow beads equilibrated with acetic acid (pH 6.0). Initial depletion of anionic components using DEAE batch adsorption reduced the recovery yield of these two proteins and did not improve recovery of any other cationic urinary proteins. We conclude that batch adsorption using SP Sepharose Fast Flow beads equilibrated with acetic acid (pH 6.0) is the method of choice to examine the basic/cationic urinary proteome, as this protocol provided the satisfactory yield of protein recovery and provided the greatest amount as well as maximal number of IFNalpha3 and EDN isoforms. Our data will be useful for further highly focused study targeting on cationic/basic urinary proteins. Moreover, the techniques described herein may be applicable for enrichment of cationic proteomes in other body fluids, cells, and tissues.