Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

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.     

The Feulgen banded karyotype of the mouse: analysis of the mechanisms of banding

The chromosomes of the mouse have been identified by specific banding patterns revealed by the Feulgen stain. Comparison of the patterns of the Feulgen-stained karyotype with those of acetic-saline-Giemsa stain and quinacrinemustard-fluorescence demonstrates a high order of similarity among the three, with the localization of Feulgen dense bands and regions closely paralleling that of Giemsa dark and fluorescence bright bands. Since the stained substrate of the Feulgen reaction is known to be DNA, it is suggested that all three banding methods reveal the distribution of DNA or of some moiety that closely follows DNA distribution in metaphase chromosomes. The preparative procedure of the Feulgen banding method consists of a 15 to 20 minute exposure to PO₄ buffer at pH 10 and a prolonged (60–72 hrs) exposure to 12xSSC. Omission or curtailment of either step results in preparations with chromosome sets that are not karyotypable, although some stain differentiation is produced. HCl extraction prior to the preparative treatment blocks banding, but acid extraction following the preparative treatment, either that of the HCl hydrolysis of the Feulgen reaction of that of an almost fourfold extension of the standard hydrolysis time, does not obliterate bands already formed. By extrapolation from biochemical studies of chromatin, it is postulated that the localization of Feulgen dark and light stain, representing relative DNA densities, reflects the regional protein association of the DNA; the Feulgen dense regions may result from aggregation of a specific class of histones by the alkaline buffer with consequent condensation of the DNA bound to those histones; the Feulgen pale or negative regions may represent those in which non-aggregated proteins, histone and non-histone, have been solubilized in the saline incubation, rendering the DNA of those regions subject to diffusion or vulnerable to fragmentation in the Feulgen hydrolysis.     

A Mordanting Fixation for Intense Staining of Small Chromosomes

A combination iron-mordant fixative in which propionic acid is substituted for acetic acid has been found useful in preparing small plant chromosomes for carmine stained squashes. Propionic acid is better than acetic acid because it holds more iron in stable solution. The fixative is a 3:1 mixture of 95% alcohol and pure propionic acid which contains 400 mg. of Fe(OH)₃ per 100 ml. of propionic acid. The latter is previously prepared by dissolving the dry freshly prepared Fe(OH)₃ in it. To each 10 ml. vial of fixative is added a few drops of carmine stain. Standard aceto-carmine squashes of material fixed in this mixture show quick intense staining and are especially useful for differentiated chromosomes at mitotic prophase.     

A Method for Combined Gross Skeletal Staining and Feulgen Staining of Embryonic Chick Tissues

This paper describes a combined technique for gross skeletal staining and Feulgen staining of avian embryonic limbs. The gross skeletal stain uses Victoria blue B, and the Feulgen stain is done en bloc before the skeletal stain is applied. The method has been useful in determining the cellular origins of supernumerary structures arising from experiments in which quail wing mesoderm is grafted into chick wing buds.     

The history,chemistry and modes of action of carmine and related dyes

Carmine has been used in biological staining to demonstrate selectively nuclei, chromosomes or mucins, depending on the formulation. Throughout its history in science, complaints and frustrations have been expressed about dye quality. Inconsistencies in dye quality or identity have prevented thorough understanding of staining mechanisms and have caused many stain solutions to behave unsatisfactorily. The aim of this review is to (1) detail causes of these problems, which are rooted in history, geography and production, (2) offer ways to minimize problems and (3) provide modern explanations for stain behavior. Carmine is a “semi-synthetic” dye, i.e., a complex of aluminum and the natural dye cochineal (carminic acid). Carmine shows considerable batch-to-batch variability. Geography, politics, history, agricultural practices and iconography all contribute to the variability of cochineal. In addition, widely divergent manufacturing methods are used to produce carmine. Also, confusion in terminology has led to mislabeling. Pressure from the food industry for a more satisfactory colorant for acidic foods led to the introduction of a new dye, aminocarminic acid, which could enter the biological market inadvertantly. Improved methods of analysis should help the certification process by the Biological Stain Commission. Further standardization could be achieved by replacing most of the methods of solubilizing carmine. The majority of these methods use heat, which is likely to damage the dye molecule. Fortunately, carmine is readily dissolved by raising the pH of the aqueous solvent above 12, and a new form of the dye, now available commercially, is soluble in water without the need for heat or pH adjustment. Chemical structures and physical properties of carminic acid, carmine, aminocarminic acid and kermesic acid are reviewed. A new configuration for carmine is proposed, as well as possible changes to carminic acid and carmine molecules as a result of decomposition caused by heating. Each of the major classes of carmine-based stains is described as are possible mechanisms of attachment to specific substrates. Glycogen binds carmine through hydrogen bonding, and it is here that carmine decomposed by heat could have the greatest detrimental impact. Nuclei and chromosomes are stained via coordination bonds, perhaps supplemented by hydrogen bonds. Finally, acidic mucins react ionically with carmine. Specificity in the latter case may be due to unique polymeric carmine molecules that form in the presence of aluminum chloride.     

Squash Method for Meiosis in Ovules

The ordinary Feulgen or acetic-lacmoid squash tech-nic following fixation in freshly made Carnoy's fluid (alcohol, 6: chloroform, 3: glacial acetic acid, 1), provides an easy and reliable method of studying meiosis in ovules. After fixation for 1 day, the material was hardened in 95% ethyl alcohol for 1-2 days and taken to water by gradual hydration. For staining by the Feulgen method, the material was hydrolyzed 8-10 minutes in 1 N HO at 58-60°C., followed by staining in decolorized leuco basic fuchsin for 2 hours. The staining was intensified by transferring the material to water. After 15-20 minutes the water was replaced by 45% acetic acid. For staining by acetic-lacmoid, the ovules after fixation, hardening and hydration were transferred to standard acetic-lacmoid stain to which was added 1 drop of 1 N HCl to every 10 drops of stain. Gentle heat was applied till the stain started to give fumes. After allowing 20 minutes at room temperature the material was transferred to fresh acetic-lacmoid. Some 6-12 ovules were mounted either in a drop of 45% acetic acid or acetic-lacmoid, depending upon the Feulgen or acetic-lacmoid staining respectively. Gentle and repeated tapping over the cover glass by a blunt needle loosened the cells of integument and nucellus and finally left the megaspore mother cells undergoing meiosis, fully exposed to view. The process was carried out under constant observation using the low power of the microscope. The desired amount of flattening was brought about by light pressure over the cover glass and gentle heating. The preparations were made permanent by dehydrating in ethyl alcohol and mounting in Euparal.     

Alcoholic Hydrochloric Acid-Carmine as a Stain for Chromosomes in Squash Preparations

A regressive bulk carmine staining schedule was adapted from a formula proposed by P. Mayer. The stain is made by boiling gently 4 gm of certified carmine in 15 ml of distilled water to which 1 ml of concentrated HC1 has been added. After cooling, 95 ml of 85% alcohol is added, and the solution filtered. Fixed tissue is soaked in the stain until thoroughly penetrated; squashes are then prepared as usual, but plain 45% acetic acid is used as the temporary mounting medium instead of aceto-carmine. The advantages of this method are: intense, precise staining of chromosomes coupled with a lightly stained cytoplasm; consistency and uniformity of results; simplicity of use.     

The history, chemistry and modes of action of carmine and related dyes

Carmine has been used in biological staining to demonstrate selectively nuclei, chromosomes or mucins, depending on the formulation. Throughout its history in science, complaints and frustrations have been expressed about dye quality. Inconsistencies in dye quality or identity have prevented thorough understanding of staining mechanisms and have caused many stain solutions to behave unsatisfactorily. The aim of this review is to (1) detail causes of these problems, which are rooted in history, geography and production, (2) offer ways to minimize problems and (3) provide modern explanations for stain behavior. Carmine is a “semi-synthetic” dye, i.e., a complex of aluminum and the natural dye cochineal (carminic acid). Carmine shows considerable batch-to-batch variability. Geography, politics, history, agricultural practices and iconography all contribute to the variability of cochineal. In addition, widely divergent manufacturing methods are used to produce carmine. Also, confusion in terminology has led to mislabeling. Pressure from the food industry for a more satisfactory colorant for acidic foods led to the introduction of a new dye, aminocarminic acid, which could enter the biological market inadvertantly. Improved methods of analysis should help the certification process by the Biological Stain Commission. Further standardization could be achieved by replacing most of the methods of solubilizing carmine. The majority of these methods use heat, which is likely to damage the dye molecule. Fortunately, carmine is readily dissolved by raising the pH of the aqueous solvent above 12, and a new form of the dye, now available commercially, is soluble in water without the need for heat or pH adjustment. Chemical structures and physical properties of carminic acid, carmine, aminocarminic acid and kermesic acid are reviewed. A new configuration for carmine is proposed, as well as possible changes to carminic acid and carmine molecules as a result of decomposition caused by heating. Each of the major classes of carmine-based stains is described as are possible mechanisms of attachment to specific substrates. Glycogen binds carmine through hydrogen bonding, and it is here that carmine decomposed by heat could have the greatest detrimental impact. Nuclei and chromosomes are stained via coordination bonds, perhaps supplemented by hydrogen bonds. Finally, acidic mucins react ionically with carmine. Specificity in the latter case may be due to unique polymeric carmine molecules that form in the presence of aluminum chloride.     

The Use of Haematoxylin for Squash Preparations of Chromosomes

A simplified propionic-iron alum-haematoxylin stain for rapid squash preparations of chromosomes requires only two stock solutions: (A) 2% haematoxylin and (B) 0.5% iron alum, both in 50% propionic acid. For use, suitable volumes of A and B are mixed. With unripened solution A, equal volumes should be used and the stain is ready for use 1 day after mixing. As the haematoxylin ripens, progressively smaller amounts of B are required and the mixture may be used immediately. The stain gives excellent results when used in the same way that orcein and carmine are currently employed, with a wide range of animal and plant (including fungal) chromosomes, and with good nucleolar staining. It may be used either following acetic alcohol (1:3) fixation or as joint fixative and stain on unfixed material. In fungal material, where Lu's BAC fixative is recommended, the centrioles are also stained.     

A Mordanting Fixation for Intense Staining of Small Chromosomes

A combination iron-mordant fixative in which propionic acid is substituted for acetic acid has been found useful in preparing small plant chromosomes for carmine stained squashes. Propionic acid is better than acetic acid because it holds more iron in stable solution. The fixative is a 3:1 mixture of 95% alcohol and pure propionic acid which contains 400 mg. of Fe(OH)₃ per 100 ml. of propionic acid. The latter is previously prepared by dissolving the dry freshly prepared Fe(OH)₃ in it. To each 10 ml. vial of fixative is added a few drops of carmine stain. Standard aceto-carmine squashes of material fixed in this mixture show quick intense staining and are especially useful for differentiated chromosomes at mitotic prophase.     

Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

Enhanced Differentiation of Zaprionus Chromosomes by Prestaining Acid Hydrolysis

Two variations of orcein staining have been adapted to salivary gland chromosomes of Zaprionus. Method I: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, stained with 2.5% orcein in 60% acetic add for 15-20 min, and squashed in 60% acetic acid. Method II: after dissection, glands are transferred to 1 N HCl at 60° C for 5 min, transferred to a saturated solution of carmine in 45% acetic acid for 1 min, then to a mixture of 50 ml of 1% orcein in concentrated lactic acid and 50 ml of 30% acetic add for 5 min. They are squashed in the same mixture. The unproved differentiation of chromosomes from cytoplasm is attributed to the removal of cytoplasmic ribonucleic add by add hydrolysis.     

G_2期后期染色质结构及染色体高级结构形成的研究

用适量BrdU处理中华大蟾蜍外周血淋巴细胞,能以较高频率得到形态多样的染色质(体)结构。本文以两栖类和人类细胞为材料,采用Feulgen染色、Ag-NOR染色、DAPI荧光染色及放射自显影等方法,证实了其染色质性质,初步讨论了其产生原因,并将其命名为:“G,期后期染色质”。在此基础上,进一步从形态学角度初步分析了从G_2期后期到M期染色质转变为染色体的动态过程,提出不同染色体形成其高级结构是非同步的,有可能存在染色体包裹顺序的设想。     

Chromatin Fluorescence after Carmine Staining

After staining with dilute solutions (0.1 mg/ml in distilled water) of commercial carmine, a strong reddish orange fluorescence was observed in nuclei from cell smears and frozen and paraffin tissue sections. Optimal exciting light ws 436 nm (violet-blue) or 450-490 nm (blue). Compact chromatin from interphase nuclei, mitotic and meiotic chromosomes and the kinetoplast of Trypanosoma cruzi showed the highest fluorescence, while the basophilic cytoplasm appeared weakly fluorescent. No emission was observed in cartilage matrix, mast cell granules or goblet cell mucin. This selective method could be valuable in microscopic and cytochemical studies on chromatin because the carmine fluorescence is stable and preparations can be dehydrated and mounted permanently without changes in the fluorescence pattern.     

Staining Plant and Animal Chromosomes by the Feulgen-Acetocarmine Sequence

A technic, some fundamentals of which were first worked out on brome grass, has been considerably extended and adapted to the somatic chromosomes of salmon. Fresh salmon eggs were quickly pierced in 45% acetic acid and fixed therein for 4 minutes. The eggs were then placed in N HCl at 60°C. for 8 minutes and thereafter transferred to Feulgen stain for 30 to 45 minutes. Subsequently, each stained embryo was dissected out and divided in two, each half being placed on a slide in a drop of acetocarmine stain. The pieces were well macerated and, after covering with a cover slip, maceration was completed by tapping. Heavy pressure was gradually applied to the cover slip in order to flatten the chromosome complements. A square screw-type laboratory hose clamp was then used to maintain this pressure while a liquid gelatin seal was applied around the edges. The slide, with the clamp on, was placed in the refrigerator overnight. Before the slide was scanned, the clamp was removed permanently. After each scanning period the slide was returned to the refrigerator. Photomicrographs of well-spread chromosomes in one optical plane were enlarged and tracings made from them. These tracings together with the photomicrographs were used for chromosome analysis.     

Basic Fuchsin as A Nuclear Stain

Five distinct nuclear stains and staining procedures which utilize basic fuchsin as the dye have been studied, compared and tested on a Feulgen-weak fungus, Blastomyces dermatitidis, and other fungi.

Aqueous basic fuchsin has been shown to be an excellent, though impermanent, stain with which to study the nuclei of this and other fungi. The conditions under which formaldehyde acts as a mordant for basic fuchsin and produces a permanent nuclear stain have been established.

Comparison of crystal violet and basic fuchsin suggests that the mordanting action of the aldehyde operates through the para-amino groups of the dye. Certain other basic dyes were not mordanted by formaldehyde.

Gentle acid hydrolysis of the tissues has been found to be essential both to the specificity of the dye as a nuclear stain and to the mordanting effect of the aldehyde.

The possible relationship of these observations to the Feulgen reaction is discussed. A protocol for the method developed is presented.     

Acridine Orange Staining and Fluorescence of Nucleic Acids in Plasmodia and Associated Host Erythrocytes

Acridine orange in daily doses of 1, 2 and 4 mg for 4 days was given to chicks averaging 50 gm in weight. Dosage was started 1, 2 and 3 days after infection with Plasmodium gallinaceum. Such doses were sufficient to stain the parasite in vivo, as shown by its bright fluorescence in UV light, but did not exhibit any antimalarial action. Staining of fresh blood samples from infected chicks with 0.01% acridine orange in Krebs-Ringer containing 0.1 M phosphate buffer (pH 6.0-6.2) resulted in differential fluorescence of the nucleic acids of the plasmodia, to show nuclear DNA bright green and cytoplasmic RNA orange-red. After optimum acid hydrolysis, as used for the Feulgen reaction, staining with 0.1% acridine orange produced intense red fluorescence of the nuclear DNA in the plasmodia. Nuclear DNA of the chick erythrocytes showed bright fluorescence both in vivo and in vitro.     

Hematoxylin Substitutes: A Survey of Mordant Dyes Tested and Consideration of the Relation of Their Structure to Performance as Nuclear Stains

In the search for hematoxylin substitutes 26 dyes were more or less extensively tested for performance as nuclear stains, usually in combination with aluminum, chromic, ferrous and ferric salts. Reports from the literature on hematoxylin substitutes were also considered, and efforts were made to obtain samples of favorably reported dyes and test them. The reports on anthocyanins include isolated reports on several berry juices and a considerable number of studies on Sambucus niger and Vaccinium mytillus. None of these have so far been tested by us. Otherwise favorable reports have appeared on eleven synthetic dyes and on carmine, brazilin, and hematein. Except for one of the synthetics, naphthazarin, which is no longer manufactured, we had samples of all of these. In addition, more or less unsuccessful trials were made on twelve dyestuffs, some of which were new syntheses designed to combine chelating capacity with nucleophilia. Following Fyg's report of blue nuclear staining with chrome alum carmine, trial was made to change the red nuclear stain of kernechtrot by altering the metal mordant.

The most successful dyes were phenocyanin TC, gallein, fluorone black, alizarin cyanin BB and alizarin blue S. Celestin blue B with an iron mordant is quite successful if properly handled to prevent gelling of solutions.     

Double Staining for Comparative Measurements in Squash Preparations

Comparative measurements of nuclei or chromosomes following different treatments are seldom made on squash preparations, since variations which arise during preparation of the slides may easily mask genuine treatment differences. This drawback may be overcome by making use of dyes which, when substituted for basic fuchsin in Schiff's reagent, will give a Feulgen-type reaction with chromatin. By selecting dyes of contrasting colours, it is possible to intermingle cells from different treatments in the same squash preparation, and to perform comparative measurements on adjacent cells.

Suitable dyes which contrast well with basic fuchsin are toluidine blue, or azure A (which stain chromatin blue) and chrysoidin yellow (which stains chromatin yellow). These dyes are made up and used in the same manner as ordinary Feulgen reagent.

Samples of cells from the two treatments to be compared are fixed, washed and hydrolysed in 1 N HCl at 60 C. One sample is stained in regular Feulgen reagent, the other in the contrast dye, then both are macerated and thoroughly mixed on the same slide in a single drop of 45% acetic acid. A coverslip is added, and the preparation flattened to the required amount and made permanent after dry-ice removal of the cover. This technique may also be utilised for comparative grain counts in autoradiography, provided that the contrast dye does not cause chemical fogging of the film.