Chromosomes in Bos Taurus as Revealed by Prefixation Treatment with Hypotonic Solutions

To study chromosomes in bull testes and their behavior at meiosis, a prefixation treatment with hypotonic solutions was used. After fixation, the material was squashed and stained with Feulgen's nucleal reaction. When needed, additional staining with iron-hematoxylin was feasible. The hypotonic Tyrode solutions of 10 to 20% normal strength were prepared according to A. Hughes (1952); the time of pretreatment was, in general, 15-30 min; fixation was made in glacial acetic acid-absolute alcohol (1:3) and Feulgen squash technic was carried out according to Schedule 5 of Darlington and La Cour (1947). Morphologic details were well preserved and photomicrographs of well-spread chromosomes in one plane were obtained easily.     

Simple Methods for Mammalian Chromosomes

The ordinary Feulgen-squash technic, after acetic-alcohol fixation, provides a simple and reliable method of preparing many mammalian tissues for chromosome counts. Tissues best suited to the technic were the seminiferous tubules. Small pieces of tissue about 3-6 mm. long and 1-2 mm. wide were immersed in a freshly made fixative (composed of 3 parts absolute ethyl alcohol and 1 part glacial acetic acid) immediately after removal by biopsy or from a freshly killed animal. After fixation for 3-12 hours the tissue was stained by the standard Feulgen procedure after hydrolysis for 12 minutes in normal HCl at 60 °C A 1-2 mm. piece was then teased apart on a slide in 45% acetic acid with a pair of mounted needles, and the teased tissue was squashed between the slide and the cover slip. During squashing the pressure was applied by hand and was regulated so as to avoid any excessive scattering of the chromosomes. The preparations were made permanent by dehydrating and mounting in Euparal.     

Gomori's Hematoxylin as a cHromosome Stain

The chromic hematoxylin of Gomori (1941) can be used as an excellent chromosome stain after hydrolysis of the tissue in warm 1-N hydrochloric acid. The hydrolysis must be accurately timed for different material as in the case of the Feulgen reaction. The staining of sections can be performed at room temperature and requires about 15 minutes. For pieces of tissue and whole preparations, it is recommended to stain at 60°C. for 40 minutes. Sections stained at room temperature can be differentiated in 1% hydrochloric acid alcohol for one minute and can be counterstained with phloxine according to Gomori's formula. Whole preparations or sections stained at 60°C. must be differentiated in 45% acetic acid for half an hour or more. Tissue pieces may, after staining, be squashed and examined in the acetic acid, but the preparations can also be made permanent. The blue-black stain is very selective and has the advantage of giving high contrast, and it is nonfading, and insoluble in water and other common reagents. It proved definitely superior to other chromosome stains for difficult material such as planarians, rabbit blastocysts, and cleavage stages of sea urchins. Though both the procedure and the result of this method show some similarity to the Feulgen reaction nothing can be said with certainty about its chemical basis.     

Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

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.     

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.     

A Universal Stain for the Sex Chromatin Body

For the demonstration of the sex chromatin body in human tissues, fixation in 95% alcohol or modified Davidson's solution (95% alcohol, 30; formalin, 20; glacial acetic acid, 10; distilled water, 30) was best. The staining procedure chosen for most materials is the following: Mounted preparations are coated with celloidin, hydrated, hydrolyzed 20 min in 52V HCl at 20-25°C, rinsed thoroughly in several changes of distilled water and transferred to a buffered thionin solution. This consists of 3 parts: (1) A saturated solution of thionin in 50% alcohol (filtered); (2) Michaelis buffer: sodium acetate (3 H₂O), 9.714 gm; sodium barbiturate, 14.714 gm; CO₂-free distilled water, 500 ml; and (3) 0.1N HCl. To make the staining solution, mix 28.0 ml of the buffer solution with 32.0 ml of 0.1N HCl and bring the total volume to 100.0 ml with the thionin solution. Its pH should be 5.7 × 0.2, and care should be exercised that no acid is carried over from the hydrolyzing solution, since this would progressively lower the pH. The staining time varies from 15 to 60 min, depending on the specimen, but the shortest time consistent with adequate staining gives the clearest preparations. Slides are rinsed in distilled water and 50% alcohol and allowed to remain in 70% alcohol until the heavy clouds of stain cease to appear. Differentiation is completed in 80% and 95% alcohol, followed by dehydration in absolute alcohol, clearing in xylene and applying a cover glass with a synthetic resin (G. T. Gurr's DePeX was used). The sex chromatin is deep blue-violet and sharply contrasted against the lightly colored particulate chromatin of the nucleus. Cytoplasm remains unstained but fibrin and related structures show metachromasia. Chromosomes are well demonstrated if present. The method works on all types of tissues, is simpler and quicker than the Feulgen method, and often yields superior results.     

The Feulgen-Picric-Acid block Stain Additional Data

Additional experiments on staining of tissues in the block by means of picric acid and the Feulgen reaction (Lhotka and Davenport, 1947) show that a variety of tissues from both plant and animal sources will respond favorably. An attempt to combine fixation and staining into a single step was not successful for mammalian tissues, but gave fair results on frog. Fixation in sublimate-acetic was unsatisfactory for block staining, and conversely, fixation in sulfosalicylic-picric gave poor Feulgen stains on the slide. Soxhlet extraction of tissue with absolute alcohol removed Feulgen positive, non-nuclear material with the exception of that in vascular endothe-lium, cartilaginous matrix and elastic tissue. After such extraction, similar results were obtained with both block and slide methods of staining.     

Staining Nerve Fibers After Sublimate-Acetic and After Bouin'S Fluid

A silver staining method for paraffin sections of material fixed in HgCl₂, sat. aq., with 5% acetic acid is as follows. Process the sections through the usual sequence of reagents, and including I-KI in 70% alcohol, thiosulfate (5% aq.), washing and back to 70% alcohol containing 5% of NH₄OH (conc. aq.). After 3 minutes in the ammoniated alcohol, wash through tap water and 2 changes of distilled water and silver 5-10 minutes at 25°C. in 15% AgNO₃ aq. to which 0.02 ml. of pyridine per 100 ml. has been added. Blot the slide, but not the section and do not rinse. Reduce at 45°C. in 0.1% pyrogallol in 55% alcohol, then rinse in 55% alcohol and wash in water. The remainder of the process consists of gold toning, intensifying in oxalic acid, fixing in 5% Na₂S₂O₃, washing, dehydrating, clearing and covering. When the specimen contains much smooth muscle, the I-KI solution is acidified before use by adding 2 ml. of 1N nitric acid per 100 ml., and the sections treated for 3 minutes instead of the usual 2 minutes. Formalin should not be added to sublimate-acetic, but specimens that do not contain strongly argyrophilic nonneural tissue may be fixed in formalin or, preferably, Bouin's fluid. Sections of tissue after the latter type of fixation will not require the I-KI and thiosulfate but can go from 95% alcohol to the ammoniated alcohol. The advantages of fixing in HgCl₂-acetic acid are suppression of the staining of connective tissue and intensifying the staining of nerve fibers.     

Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

Block staining of mammalian tissues with hematoxylin and eosin

Various mammalian tissues were stained en bloc with hematoxylin and eosin after fixation and prior to embedding in paraffin wax and sectioning. The choice of fixative is important and best results are obtained using Worcester's Fluid, a combination of saturated aqueous mercuric chloride, formaldehyde, and glacial acetic acid. After fixation, blocks of tissue up to 1.5 cm thick are stained for seven days in hematoxylin. Excess stain is removed by washing tissues in running water overnight. Tissue blocks then are dehydrated with graded concentrations of ethyl alcohols to 80% and counterstained, with further dehydration, in 0.5% spirit soluble eosin in 90% ethyl alcohol for five days. The tissue is subsequently transferred to 90% ethyl alcohol overnight to differentiate eosin staining; dehydration is completed in absolute ethyl alcohol. The blocks are cleared in in cedarwood oil and briefly in xylene prior to embedding, sectioning, and mounting. Following removal of wax by xylene, coverslips are applied. General morphological and histological features were particularly well differentiated and very selectively and reliably stained by this method.     

Block Staining of Mammalian Tissues with Hematoxylin and Eosin

Various mammalian tissues were stained en bloc with hematoxylin and eosin after fixation and prior to embedding in paraffin wax and sectioning. The choice of fixative is important and best results are obtained using Worcester's Fluid, a combination of saturated aqueous mercuric chloride, formaldehyde, and glacial acetic acid. After fixation, blocks of tissue up to 1.5 cm thick are stained for seven days in hematoxylin. Excess stain is removed by washing tissues in running water overnight. Tissue blocks then are dehydrated with graded concentrations of ethyl alcohols to 80% and counterstained, with further dehydration, in 0.5% spirit soluble eosin in 90% ethyl alcohol for five days. The tissue is subsequently transferred to 90% ethyl alcohol overnight to differentiate eosin staining; dehydration is completed in absolute ethyl alcohol. The blocks are cleared in cedarwood oil and briefly in xylene prior to embedding, sectioning, and mounting. Following removal of wax by xylene, coverslips are applied.

General morphological and histological features were particularly well differentiated and very selectively and reliably stained by this method.     

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.     

Rapid Staining of Nuclei and Chromosomes in Root Tips

Feulgen reagent quickly heated to and maintained at 60 C just before immersion of plant material, basic fuchsin in acid alcohol at room temperature, and pinacyanol at room temperature will stain hydrolyzed root tip nuclei and chromosomes in one minute or less. This technic, coupled with fast fixation, can be utilized when uncertainties exist as to when to begin sampling plant meristem cells for mitoses or when time does not allow for standard fixation and Schiff staining.     

Preparation of Chromosomes of Tetrahymena Pyriformis for Photomicrography

Conjugating animals of the protozoan, Tetrahymena pryiformis, were affixed to cover slips by means of Nissenbaum's fluid, followed immediately by 1:3 acetic-alcohol for 18-24 hr. After fixation, the material was transferred through a descending alcohol series to water, then hydrolyzed in 1 N HCl, washed in water, followed by immersion in 45% acetic acid and subsequent mounting in aceto-carmine. Photomicrographs were made using a phase-contrast microscope and Microfile film. The schedule resulted in preparations with abundant material, adequate spacing of chromosomes in a single plane, and excellent differentiation of the chromosomes from the cytoplasm.     

Permanent Mounts Of Chromosomes After 8-Oxyquinoline and Squashing

Fresh young root tips or free-hand cross sections thereof were placed in 0.002 M 8-oxyquinoline (aq.) at 10-14^oC. for 3 hours. After rinsing in water 1-2 minutes, they were soaked in N HC1 at 55^oC. for 25 minutes, rinsed again and squashed under a cover glass on a dry slide. Slide and cover glass were separated by placing in 70% alcohol and allowed to remain therein at least 0.5 hour after separation. Both slide and cover glass were passed through 50% and 30% alcohol to water and stained by the Feulgen procedure (without further hydrolysis) or with crystal violet after mordanting in 1% chromic acid overnight and washing in running water 3-4 hours. Dehydration and mounting in balsam completed the process. The smear on the slide was covered with a clean cover glass and the cover glass, bearing stained material, mounted separately.     

Toluidine Blue-Alizarin Red S Staining of Cartilage and Bone in Whole-Mount Skeletons in Vitro

Cartilage and bone of the developing skeleton can be reliably differentiated in whole-mount preparations with toluidine blue-alizarin red S staining after FAA fixation. The recommended staining procedure is based chiefly on the use of newborn white and Swiss-Webster mice, 4-9 days postnatal, but was tested also on mice and rats 3-8 wk of age. Procedure: Sacrifice, skin, eviscerate, remove body fat, and place specimens in FAA (formalin, 1; acetic acid, 1; 70% alcohol, 8) for approximately 40 min. Stain in 0.06% toluidine blue made in 70% ethyl alcohol for 48 hr at room temperature. Use 20 volumes of stain solution to the estimated volume of the specimen. Destain soft tissues in 35% ethyl alcohol, 20 hr; 50%, 28 hr; and 70%, 8 hr. Counterstain in a freshly prepared 1% aqueous solution of KOH to which is added 2-3 drops of 0.1% alizarin red S per 100 ml of solution. Each day for 3 days, transfer the specimen to a fresh 1% KOH-alizarin mixture, or until the bones have reached the desired intensity of red and soft tissues have cleared. Rinse in water, and place in a 1:1 mixture of glycerol and ethyl alcohol for 1-2 hr, then transfer the specimen to fresh glycerol-alcohol for final clearing and storage. Older mice and rats require procedural modifications: (1) fixation for 2 hr, (2) 0.12% toluidine blue, (3) maceration for 4 days in 3% KOH-alizarin, and (4) preliminary clearing for 24 hr in a mixture of glycerol, 2; 70% ethyl alcohol, 2; and benzyl alcohol, 1 (v/v) before placing in a 1:1 alcohol-glycerol mixture.     

Differential Staining Of Tissue In The Block With Picric Acid And The Feulgen Reaction

The authors have found a modification of the Feulgen reaction to be a satisfactory stain for tissue in the block.

Pieces of fresh mammalian tissue not thicker than 5 mm. are fixed for approximately 48 hours at 25° C. in a mixture of equal parts of 5% aqueous sulfosalicylic acid and saturated aqueous picric acid. They are washed for 30 minutes in three ten-minute changes of distilled water and placed in Feulgen's staining solution diluted to one-half strength with distilled water. The staining solution is allowed to act for 24 hours (2 to 3 mm. thick blocks) up to 48 hours for 5 mm. thickness. After staining, the specimens are transferred to a mixture of sodium bisulfite, 0.5 g. and N hydrochloric acid, 5 ml. in' 100 ml. of distilled water. Two changes of IS to 30 min. each in the acid sulfite are given and these are followed by dehydration through 50%, 70% and 95% alcohol. One to two hours are allowed for each change except the last 95%, in which the stained tissue is allowed to remain overnight. The dehydration is completed in two changes of absolute alcohol with subsequent clearing in xylene and embedding in paraffin. Sections may be cut 10 μ or other thickness desired, mounted on slides, paraffin removed, and covered in the usual manner. Nuclei stain reddish violet against a lemon yellow background when the stain is typical. Orange G, 200 mg. per 100 ml. may be added to the fixing fluid if a more polychromatic effect is desired.     

Confocal microscopy of whole ovules for analysis of reproductive development: the elongate1 mutant affects meiosis II

Analysis of female meiosis (megasporogenesis) and embryo sac development (megagametogenesis) in angiosperms is technically challenging because the cells are enclosed within the nucellus and ovule tissues of the female flower. This is in contrast to male sporogenesis and gametogenesis where development can readily be observed through the easily dissectable developing anthers. Observation of embryo sac development is a particular problem in crassinucellate ovules such as those of maize. To overcome the problems in observing reproductive development, we developed a simple Feulgen staining procedure optimized for use with confocal microscopy to observe reproductive progression in the crassinucellate ovules of maize. The procedure greatly facilitates the observation of nuclei and cell structures of all stages of megasporogenesis and embryo sac development. The high resolution obtained using the technique enabled us to readily visualize chromosomes from individual cells within ovule tissue samples of maize. A propidium iodide staining technique was also used and compared with the Feulgen-based technique. Static cytometry of relative DNA content of individual nuclei was possible using Imaris software on both Feulgen and propidium iodide-stained samples. The techniques also proved successful for the observation of Arabidopsis and Hieracium aurantiacum female gametophyte and seed development, demonstrating the general applicability of the techniques. Using both staining methods, we analysed the maize meiotic mutant elongate1, which produces functional diploid instead of haploid embryo sacs. The precise defect in meiosis from which diploid embryo sacs arise in elongate1 has not previously been reported. We used confocal microscopy followed by static cytometry using Imaris software to show that the defect by which diploid embryo sacs arise in the maize mutant elongate1 is the absence of meiosis II with one of the dyad cells directly initiating megagametogenesis.     

Procedure to Facilitate Chromosome Counts in Difficult Plant Material

Numerous mitotic plates of contracted and well-spread chromosomes may be obtained from root tips of plants set on melting ice or snow overnight at room temperature. After 1:3 acetic-alcohol fixation for 0.5 to 3 hours the material is mordanted in a mixture of 7 parts of alcohol plus 21/2 parts of 3% ferric ammonium sulfate for 3 hours to overnight. This solution may be used as storage fluid for flower buds. Deep chromosome coloration without precipitates is secured by staining in a few drops of aceto-carmine for 10-15 minutes after which the tissues are softened by heating in aceto-carmine diluted with 3 parts of 45% acetic acid.