An Acetocarmine Technic for Cucurbita

Staminate Cucurbita buds undergoing meiosis are fixed for 12-24 hours in a solution containing 3 parts of 95% alcohol, 1 part of acetocarmine to which iron acetate has been added, and a flake of rusted iron. After fixation the buds are washed in 95% alcohol and stored in 95% alcohol with the iron flake for 5-10 days. A stain containing 10 drops of 45% acetic acid, 10 drops of acetocarmine, and 10 drops of brown storage solution is prepared. A small piece of anther is placed in a drop of stain on a slide. At the moment the anther is macerated, the debris is removed, and when the cells turn grey to dark brown a cover slip is applied. The stain is differentiated by gentle heat and the cover slip is sealed with paraffin.     

<Emphasis Type="Italic">Hieracium</Emphasis> subgen. <Emphasis Type="Italic">Pilosella</Emphasis>: pollen stainability in sexual,apomictic and sterile plants

Two pollen stainability tests (Alexander’s stain and acetocarmine) were used to detect differences in pollen viability of the sexual, apomictic and sterile plants of Hieracium subgen. Pilosella. In sexual taxa (Hieracium bauhini and H. densiflorum), the average stainability was 93.7–98.4%. Similarly high stainability (92.2–97.2%) was found in the apomictic Hieracium pilosellinum and in the majority of the apomictic populations (or plants) of the pentaploid and hexaploid H. bauhini. In some apomictic plants of Hieracium bauhini the average pollen stainability was 49.0–75.4%. The lowest pollen stainability was found in the sterile plants, i.e. the triploid H. pistoriense (33.6%) and the pentaploid H. brachiatum (29.6%).     

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.     

A Controllable Carmine Technic for Plants with Small Chromosomes

Anthers of small chromosome plants (Antirrhinum, Brassica, Capsicum etc.) were fixed 12 hours or longer at 0-3° C. in: ferric acetate in glacial acetic acid (sat. soln.), 1 part; absolute alcohol, 3 parts. They were transferred to: ferric acetate (sat. soln.) in 45% acetic acid, 3 parts; 45% acetic acid, 5 parts; 1% formalin (aq.), 2 parts, and allowed to remain 5-15 minutes at room temperature for mordanting. The amount of iron introduced into the specimens was controllable by the time in the mordanting fluid. After rinsing the specimen in 45% acetic acid and macerating in a drop of Belling's acetocarmine on a slide, a cover slip was applied followed by warming and pressing with blotting paper to flatten the pollen mother cells and expel excess stain. Preparations stored temporarily by sealing the edges of the cover slip with rubber solution were best made permanent by removing the cover slip after 1-2 days, dehydrating and mounting in euparal.     

Romanowsky-type staining: Enzymatic analysis of nuclear metachromasia in formalin-fixed paraffin sections

The red color of nuclei produced in formol-fixed paraffin sections stained with toluidine blue has been investigated by using deoxyribonuclease (DNase), ribonuclease (RNase) and 0.1 M Tris buffer. The action of DNase on formol-fixed material is not fully reliable, but clear-cut when positive. Nuclear basophilia and metachromasia is removed, nucleolar and cytoplasmic RNA is preserved. The picture produced by RNase depends to some extent on the concentration and acidity of the toluidine blue used for subsequent staining. Cytoplasmic RNA is always removed, while the red stain in nuclei usually remains intact. With 0.1% toluidine blue in 1% acetic acid, a nuclear color change from red to pale green is observed. Using this same staining solution, it can be shown that 0.1 M Tris buffer (overnight extraction at 37° C) will remove cytoplasmic RNA but leave intact the nuclear material that stains red. A red to green shift can subsequently be produced by RNase. From this it is deduced that there is a chromatin-associated nuclear RNA fraction which can be removed by the enzyme, but is stable to the buffer solution.     

A Technic for Differential Staining of Nucleoli and Chromosomes

A procedure is described which enables a stain to be definitely located in the substance of the nucleolus. Material is fixed in either Navashin or Levitsky; the chromatin is stained by means of the improved Feulgen technic introduced by de Tomasi, and preparations brought thru the washing solutions down to distilled water. From distilled water the material is transferred to a mordant solution, 5% sodium carbonate in water, in which it is left for at least one hour. After mordanting wash well with water then stain for ten minutes in light green solution (90% alcohol, 100 cc, light green SFY, 0.5 g, aniline oil, 2 drops, well shaken); differentiate in alcoholic sodium carbonate solution, (70% alcohol saturated with carbonate); treat with 95% alcohol, absolute alcohol, equal parts xylene and absolute alcohol, clear in pure dry xylene and mount in neutral balsam. Cytoplasm and karyolymph should be quite clear, with magenta chromatin and well defined green nucleoli. The light green does not behave like a simple counterstain as in previous technics but as a definite stain for nucleolar material.     

An Improved Method of Decalcification

Following several experimental investigations, an improved method of decalcification has been devised. The principle of this decalcification method is to obtain complete decalcification by a mixture of as high pH as possible without diminishing the stainability of the Nissl-granules (with Einarson's progressive staining method by means of gallocyanin). This is accomplished by the help of a buffer solution of equal parts of 8 N formic acid and 1 N sodium formate (pH 2.2). After-treatment consists only in rinsing in flowing water for 24 hours. Dehydration is in alcohol (70%, 96%, 100%); cedar oil; ligroin. Embedding in paraffin follows.     

A simple method for staining nuclei of mature and germinated maize pollen

A sugar acetocarmine staining technique has been developed for staining the sperm and vegetative nucleus of mature and germinated maize pollen grains. This procedure is simple, stable and highly repeatable. The physiological properties of the mature maize pollen grains are first adjusted by using an in vitro germinating culture solution. This solution is 15% sucrose and contains 360 ppm calcium chloride dihydrate, and 120 ppm boric acid. One part fresh pollen grains is uniformly mixed with nine parts of the solution and left at room temperature for at least 5 hr. One part of this solution is then mixed with two parts of regular acetocarmine stain and left overnight. The color of this mixture is pinkish red or raspberry. The sugar in the mixture helps to increase color contrast between the pollen cytoplasm (light pink) and the nuclei (reddish purple), decreases the frequency of burst pollen, increases pollen expansion, stabilizes pollen figures and automatically seals the coverglass.     

Permanent Preparations from Rapid Cytological Technics

The following rapid but reliable method of making permanent preparations from temporary mounts has proved to be very useful.

Pollen mother-cell smears: Smeared anthers are treated hi the usual way with Belting's acetocarmine, except that the cover slip is left off. When correct differentiation is attained the stain is thoroly washed off with 50% acetic acid and the slide flooded with dioxan. This is followed by 2 changes of dioxan for 2 minutes each. A drop of Canada balsam dissolved in dioxan is added and a cover slip applied. In cases where a cover slip has been used at the acetocarmine stage it can be floated off in a staining jar of 50% acetic acid and dehydration with dioxan carried out as above.

Insect salivary gland chromosome smears: The glands are crushed under a cover slip in acetocarmine on a slide coated with dried egg albumen. After 20 minutes the area around the cover slip is flooded with 50% acetic acid and the cover slip floats loose so that it can be removed. The above described dioxan dehydrating procedure is then employed.

Squash preparations: Root tips are fixed in some suitable fixative and the Feulgen technic applied. The stained root tips can either be dehydrated by passing thru 3 changes of dioxan and mounting in dioxan-balsam where they are divided into small longitudinal sections by sharp needles, or they can be put immediately into a mixture of 1 part of 50% acetic acid to 1 part of corn syrup where shredding with needles is carried out. A cover slip is put on and separation of the cells completed by tamping or by applying pressure to the cover. This squash method is useful with anthers which are difficult to smear when in the early prophase stages of meiosis.     

A Differential Stain Favorable to the Diagnosis of Neisserian Infection

A differential Gram stain has been evolved which incorporates the combined features of the original Gram and Pappenheim methods. National Aniline crystal violet and new methyl green and pyronin are the dyes preferred. The iodine mixture of Kopeloff and Beerman is a satisfactory mordant and Merck's pure technical acetone is an excellent differentiating agent. A system is established by means of the dyes and reagents which form a physicochemical equilibrium, provided pure dyes are employed, and the technic is carried out with precision. Gram-positive bacteria are coated by means of buffered crystal violet solution and the iodine-sodium hydroxide solution precipitates the crystal violet from other substances. The dye-iodine precipitate is readily dissolved by pure acetone. Iodine green, a pure derivative of crystal violet has the effect of noninterference in the technic and has selective action upon nuclear substance. Pyronin has affinity for Neisserian organisms primarily and acts as an inert substance upon most other proteins, (except cytoplasm of eosinophils, lymphocytes, plasma cells, and endothelial cells). The following technic is recommended:

Stain air-dry films 3 to 5 minutes in a 1% solution of crystal violet in 10 parts of Clark and Lubs' phosphate buffer of pH 6.6 to 7.0 and 90 parts water. Decant and flush with 2% iodine in N/10 NaOH. Decant and decolorize in acetone 10 seconds or less. Air dry and counterstain 1 1/2 to 2 minutes with methyl-green-pyronin (2 parts 2% aqueous methyl green National with one part 0.3% aqueous pyronin yellowish). Wash and air dry. Oil of Bergamot is preferable to xylene as a clearing agent. Best results are obtained if each slide is handled separately as for staining blood films.     

Simple Aids to Microscope Illumination

The following rapid but reliable method of making permanent preparations from temporary mounts has proved to be very useful.

Pollen mother-cell smears: Smeared anthers are treated hi the usual way with Belting's acetocarmine, except that the cover slip is left off. When correct differentiation is attained the stain is thoroly washed off with 50% acetic acid and the slide flooded with dioxan. This is followed by 2 changes of dioxan for 2 minutes each. A drop of Canada balsam dissolved in dioxan is added and a cover slip applied. In cases where a cover slip has been used at the acetocarmine stage it can be floated off in a staining jar of 50% acetic acid and dehydration with dioxan carried out as above.

Insect salivary gland chromosome smears: The glands are crushed under a cover slip in acetocarmine on a slide coated with dried egg albumen. After 20 minutes the area around the cover slip is flooded with 50% acetic acid and the cover slip floats loose so that it can be removed. The above described dioxan dehydrating procedure is then employed.

Squash preparations: Root tips are fixed in some suitable fixative and the Feulgen technic applied. The stained root tips can either be dehydrated by passing thru 3 changes of dioxan and mounting in dioxan-balsam where they are divided into small longitudinal sections by sharp needles, or they can be put immediately into a mixture of 1 part of 50% acetic acid to 1 part of corn syrup where shredding with needles is carried out. A cover slip is put on and separation of the cells completed by tamping or by applying pressure to the cover. This squash method is useful with anthers which are difficult to smear when in the early prophase stages of meiosis.     

Basic Two-Dye Stains for Epoxy-Embedded 0.3-1 μ Sections

Dyes used in the 3 methods recommended are: I, thionin and acridine orange (T-AO); II, Janus green and Darrow red (JG-DR); III, methyl green and methyl violet (MG-MV). The first 2 methods were two-solution stains, applied in sequence; the third, required only one solution since methyl violet is present in commercial methyl green. Staining solution and timing was as follows: Method I. 0.1% thionin in a 45% ethanolic solution of 0.01 N NaOH, 5 min at 70 C; rinsing in water and followed by 1 min in a 1% aqueous solution of acridine orange made up in 0.02 N NaOH, also at 70 C, then washed, and dried on slides. Method II. 0.5% Janus green in aqueous 0.05 N NaOH, 5 min at 70 C; rinsing in water then into 0.5% Darrow red in 0.05 N NaOH (aq.), 2 min at 70 C., washing, and drying on slides. Method III. 1% methyl green (commercial, unpurified) in 1% aqueous borax for 15-20 min at 20-25 C, washing and attaching to slides. All staining was performed by floating the sections on the staining solutions, all drying at 70 C, and mounting in a resinous medium. T-AO gave blue to violet cytoplasmic structures, darker nuclei which contrasted strongly with yellow connective tissue and the secretion of goblet cells. JG-DR resembled a hematoxylineosin stain, but by shortening the staining time in DR to 0.5-1 min, collagenous and elastic tissue retained more of the green dye. MG-MV gave dark green nuclei in light green cytoplasm, with collagenous and elastic tissues in blue to violet. As with most methods for staining ultrathin sections, thicknesses of less than 1 μ required longer staining times.     

Brilliant Cresyl Blue as A Stain for Chromosome Smear Preparations

Brilliant cresyl blue is substituted for carmine in the acetocarmine technic. A mixture of one part of 1% toluidine blue and three parts 0.75% brilliant cresyl blue dissolved in 45% acetic acid gives good results. Propionic acid may be used instead of acetic acid for more rapid penetration.     

Chlorazol Black E As An Aceto-Carmine Auxiliary Stain

In making chromosome counts on plants and plant parts treated with colchicine it was found that in cases where aceto-carmine alone is not satisfactory—as in axillary buds of apple, pear, plum, peach, apricot, and cherry—the following method was effective : Dissect out the meristematic parts of the axillary bud under a binocular (or cut free-hand sections) and transfer the dissected tissue immediately to a solution of 3 volumes alcohol to 1 volume acetic acid for killing and fixing. Let the fixative act at least 10 minutes; a longer time, 12-24 hours, improves the staining quality. Wash in at least 3 changes of 70% alcohol to remove most of the acid. Stain for 5-25 minutes in 1% chlorazol black E² in 70% alcohol. Rinse in 3 changes of 70% alcohol to remove excess stain. Transfer the material to a slide, cover with a drop of aceto-carmine, and if necessary, dissect further under a binocular. Cover with cover glass, heat, flatten and seal, or run Zirkle's fluid under the cover for permanent mounting. For smears of sporocytes, chlorazol black E may also be employed alone, or in combination with aceto-carmine, if a dark purple nuclear stain is desired.     

Feulgen DNA stainability of bone tumors after demineralization

Microspectrophotometric DNA analysis of archival bone tumor tissue is often impeded by previous acid demineralization, which destroys Feulgen DNA stainability. To find an alternative to acid for prospective DNA studies of bone tumors in tissue sections, Feulgen stainability of fresh osteosarcoma specimens after demineralization in neutral EDTA was investigated. The reliability of DNA analysis of weakly Feulgen-stained sections from archival tissue was also studied. Demineralization of four fresh specimens in EDTA slightly reduced Feulgen DNA stainability compared to nondemineralized preparations but did not affect the determination of ploidy level. Hydrolysis tests of one diploid and one hyperploid osteosarcoma showed that the staining relationship between control and tumor cells was not altered by EDTA pretreatment. For DNA studies of bone tumors requiring demineralization, EDTA offers a means of retaining nuclear Feulgen stainability. In 22 archival osteosarcoma specimens of varying Feulgen stainability, three different upper limits of light transmission (75, 85, and 95%) were applied to test the significance of background disturbances in relation to nuclear stain intensity. The relationship between the median total extinction of the control and tumor cell populations was not significantly affected by altering the upper transmission limit except in four poorly stained lesions. The control cells of these four specimens exhibited a median total extinction less than one-third of the maximum encountered. The results suggest that weakly stained archival specimens can be tested for selecting those appropriate for ploidy determination.     

Staining and Washing Ultrathin Sections; a Device for Handling Various Materials Simultaneously

To eliminate individual manipulation, as many as 10 grids, each held firmly by a small notched bar of polyethylene plastic, are simultaneously stained, then washed. If the stain used is reactive with atmospheric CO₂ it can be forced through a Millipore filter into a small chamber made of glass tubing which contains the grid holder. The stain, cleared of any solid particles, has very little contact with air and remains free of lead carbonate contamination. Washing is carried out by submerging the chamber and removing the grid holder under water (Feldman, D. G., J. Cell Biol., 15: 592-5, 1962). Washing is minimized because there is not the risk of contaminating grids and wash water with stain trapped between the points of forceps. The polyethylene is nonadherent to the wash water, and the grids can therefore be dried quickly on the holder. With this method, the relative stainability of different materials may be observed because each grid within a batch receives identical treatment.     

A Controllable Carmine Technic for Plants with Small Chromosomes

Anthers of small chromosome plants (Antirrhinum, Brassica, Capsicum etc.) were fixed 12 hours or longer at 0–3° C. in: ferric acetate in glacial acetic acid (sat. soln.), 1 part; absolute alcohol, 3 parts. They were transferred to: ferric acetate (sat. soln.) in 45% acetic acid, 3 parts; 45% acetic acid, 5 parts; 1% formalin (aq.), 2 parts, and allowed to remain 5–15 minutes at room temperature for mordanting. The amount of iron introduced into the specimens was controllable by the time in the mordanting fluid. After rinsing the specimen in 45% acetic acid and macerating in a drop of Belling's acetocarmine on a slide, a cover slip was applied followed by warming and pressing with blotting paper to flatten the pollen mother cells and expel excess stain. Preparations stored temporarily by sealing the edges of the cover slip with rubber solution were best made permanent by removing the cover slip after 1–2 days, dehydrating and mounting in euparal.     

Sudan Black B And Acetocarmine as a Combination Stain

Epidermis stripped from either fresh or fixed plant organs, or sections of paraffin-embedded or fresh material are placed on a slide and covered with a drop or two of iron-acetocarmine. The stain is intensified by warming the slide over a flame. After a few minutes a drop or two of a saturated solution of Sudan black B in 45% acetic acid is added and a cover slip applied. The preparations cannot be made permanent, but last a few weeks if sealed with a compound such as gum mastic-paraffin, or if the combined stain is drained off and a drop of Karo syrup is added before the cover slip is applied. The acetocarmine produces its usual staining effects, i.e., nuclei dark red and some components of the cytoplasm of certain cells a less intense red. The Sudan black B colors lipid structures an intense blue.     

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.