A Paradichlorobenzene, Saponin, Iron Mordant Sequence in the Staining of Meiotic Chromosomes of Ipomea

For the meiotic study of Ipomea spp., flower buds were stripped of the calyx and corolla and soaked in saturated aqueous paradichlorobenzene at about 28° C for 3 hr, transferred to acetic-alcohol (1:3) for 6 hr, then into 1% saponin solution and left overnight. They were mordanted in 1:3 acetic-alcohol saturated with ferric oxide for 24 hr and stained in a mixture of 1% aceto-carmine and 2% aceto-orcein with 1 N HCl in the proportion of 9:9:1. The preparations were mounted in 1% aceto-carmine for temporary use and made permanent by dehydration through the n-butanol schedule. The pollen mother cells had clear cytoplasm with deeply stained chromosomes.     

Air drying method using nitrous oxide for chromosome counting in maize

Nitrous oxide (N₂O), colchicine, trifluralin, amiprophos-methyl, 8-hydroxyquinoline, and temperature pretreatments (cold and cold-hot-cold) were compared for chromosome counting in maize (Zea mays L.). Pretreated root tips were prepared by enzymatic maceration and air drying, and the number of countable figures and mitotic indexes were recorded. N₂O treatment at 10 atm for 3 hr produced the largest number of countable chromosome figures (266.5 per preparation) and an average of 44.2 nonoverlapped chromosome figures per preparation. Treatment with 0.04% 8-hydroxyquinoline for 3 hr exhibited a moderate number of countable chromosome figures (53.9 per preparation). The effects of colchicine, trifluralin, amiprophos-methyl and temperature pretreatments were limited.     

Permanent Mounting of Unstained and Aceto-Orcein Stained Cells in the Water-Soluble Medium, Abopon

For cellular morphology, mammalian cells were grown on cover slips in Leigh ton tubes, fixed in 1% osmic acid vapor for 2 min, decolorized with 30% H₂O₂ in 5% ammonium oxalate solution (1:7) for 2 min, then washed thoroughly, and finally mounted in a water-soluble medium consisting of a saturated solution of Abopon in 0.2 M phosphate buffer, pH 7.0. For chromosomal analysis of similarly cultured cells, aceto-orcein preparations were made by conventional methods, with the following minor modifications: following pretreatment with colchicine and hypotonic expansion, the cells on the cover slips were fixed in acetic-alcohol (1:3), air dried, incubated at 37° C for 15 min in 2% orcein in 45% acetic acid, rinsed in 45% acetic acid, washed several times in distilled water, and finally mounted in Abopon mounting medium. Both kinds of preparations were allowed to harden for 24 hr before being handled. Such slides will keep for years at room temperature. Studies requiring frequent comparisons of cellular and chromosomal morphology of cultured cells can thus be extended over long periods of time.     

A Pollen Grain Squash Technique for Saccharum and Related Genera

Anthers collected between 9 and 10 AM were treated for 1 hr at 26-28 C with a 0.5% solution of colchicine, washed for 2-4 min in water, placed in 0.002 M 8-hydroxyquinoline for 1 hr, washed in water for 10 min and fixed in: methanol, 60 ml; chloroform, 30 ml; distilled water, 20 ml; picric acid, 1 gm and mercuric chloride 1 gm, for 24 hr. After washing they were hydrolysed in 1 N HCl for 15 min at 60 C, stained in leuco basic fuchsin for 30 min, then smeared on a slide in a drop of acetocarmine. The slides were sealed, stored overnight, the paraffin was removed, and the slide passed through a 1:1 mixture of n-butyl alcohol and acetic acid, then through pure n-butyl alcohol and mounted in Canada balsam. The significant features of this procedure are: (1) use of chromosomes in the haploid condition for karyotype analysis, (2) better exaggeration of constrictions for easier interpretation of chromosome types and (3) good spreading in plants with a large chromosome number.     

Chromosome Preparations in the Field from Mammals Long After Death

Chromosome preparations of high quality can be obtained from bone marrow cells of small mammals that have been dead for 20 hr or longer. The bone marrow is rinsed out of the femurs with RPMI medium supplemented with 15% fetal calf serum. Add 0.05-0.1 ml of a 0.01 % colchicine solution to 5 ml of medium-cell suspension. After Vi-1 hr of colchicine treatment at 37 C the cells are spun down and the supernatant replaced by 5 ml of hypotonic (0.075 M) KC1. After 12 min in the hypotonic solution at 37 C the cells are fixed in methanokacetic acid 3:1. Air dried preparations are made after repeating the fixation procedure three times and the chromosomes are stained with Gietnsa, if required after prclieatment of the preparations for banding; e.g., GTG. Technical hints for field work are given. The technique has proven successful with several species of rodents and shrews.     

Chromosome preparations in the field from mammals long after death

Chromosome preparations of high quality can be obtained from bone marrow cells of small mammals that have been dead for 20 hr or longer. The bone marrow is rinsed out of the femurs with RPMI medium supplemented with 15% fetal calf serum. Add 0.05-0.1 ml of a 0.01% colchicine solution to 5 ml of medium-cell suspension. After 1/2-1 hr of colchicine treatment at 37 C the cells are spun down and the supernatant replaced by 5 ml of hypotonic (0.075 M) KCl. After 12 min in the hypotonic solution at 37 C the cells are fixed in methanol:acetic acid 3:1. Air dried preparations are made after repeating the fixation procedure three times and the chromosomes are stained with Giemsa, if required after pretreatment of the preparations for banding, e.g., GTG. Technical hints for field work are given. The technique has proven successful with several species of rodents and shrews.     

Physiological Saline Solutions as a Useful Tool in Micronucleus and Metaphase Slide Preparations

The micronucleus test (Schmid 1975) is widely used as an indicator of cytogenetic damage induced in vivo by clastogens and spindle poisons. Yamamoto and Kikuchi (1980) have recently showed that by comparing the relative size of micronuclei it is possible to determine whether an agent acts as a clastogen or a spindle poison. This finding will undoubtedly increase the use of the technique in routine protocols for the testing of chemicals. Besides, the test is quite sensitive and much simpler and faster than chromosome analysis. One obstacle, however, hinders several laboratories: the increasing unavailability of fetal calf serum. Recently, Das and Kar (1980) have proposed sodium citrate as a substitute for fetal calf serum. However, 1% sodium citrate solution is hypotonic, which fact may pose difficulties for an experimenter having to sacrifice several animals within a short time, a common situation in routine tests. We were able to overcome the problem of hypotonia by replacing fetal calf serum with the isotonic solutions 0.9% NaCl and Ringer's saline for mammals (9.00 g NaCl, 0.42 g KCl, 0.24 g CaCl₂, 0.20 g NaHCO₃, 1000 ml distilled. H₂O) at room temperature.     

Application of Methods for Mammalian Chromosome Spreads to the Cells of Cestodes

Tapeworm cells obtained by physical maceration between ground-glass surfaces are incubated for 3 hr in Hanks' balanced salt solution (BSS) supplemented with colchicine to a concentration of 10-⁴ M. After washing in BSS, the cells are incubated for 10 min in 1/4 strength BSS then centrifuged 10 min. Fixation of the intact button of cells (or alternatively, by squirting the cells directly into the fixative) in Carnoy's alcohol-chloroform-acetic acid (6;3:1) for 30 min follows, and cells, dispersed and washed in the fixative, are flattened by dropping the suspension on clean, water-wet slides which are then air-dried and stained with Giemsa diluted 1 ml;47 ml with distilled water to which 2 ml of buffer—M/15 KH₂PO₄, 32 ml, mixed with M/15 Na₂HPO₄, 68 ml—is added. After staining 15 min and washing in distilled water, slides are air-dried and mounted with resin. Well separated and well stained chromosomes have resulted.     

Chromosome Preparatons of Bone Marrow Cells without Prior In Vitro Culture or In Vivo Colchicine Administration

Bone marrow (about 0.5 ml) from au erythropoietic region is freed of blood clots by washing 1-3 min in 1 μg/ml colchicine solution (2-3 ml) and then soaking 1-2 hr at 20-30° C in a second change. For mammalian or avian marrows, the colchicine is made up in phosphate-buffered (pH 7) physiological NaCl solution; for amphibian, Ringer's A solution. Next the specimens are soaked about 20 min in a hypotonic solution as follows: for mammalian, 1% Na-citrate; for avian, a 1:4 dilution of the buffered NaCl solution by distilled water; and for amphibian, Ringer's A-distilled water, 1:1. Then they are heated in a mixture of 2% orcein in 45% acetic acid and 1 N HCl, 9:1. Immediately after heating, squash preparations are made with 2% acetic-orcein in the usual manner. An alternative method is to dissociate the marrow cells by agitating after colchicine treatment. Then, recovering the cells between changes by low-speed centrifugation, to carry out the hypotonic treatment and subsequent fixation in Carnoy's solution I (alcohol acetic, 3:1) before drying the cells onto slides from the fixative. After thorough drying the slides may be stained 10-20 min in acetic orcein, or by other suitable technics.     

Injection of Lymphatics: With Colored Cedar Oil; With Plastic

(1) The oil mass consists of: cedar oil, 1; color in oil (a paint pigment, e.g., Prussian blue), 1; and toluene, 2, parts by volume. To use, add 1 ml of diethyl ether to each 10 ml of mass, mix thoroughly and inject into the fresh organ with a very fine glass or metallic needle. Heat the organ in water at 50-60° C before starting the injection, massage gently after injection, then fix. For macroscopic studies, fix 5 days in 5% formalin, and dissect. For microscopic studies, fix at least 5 days in: formalin, 10 ml; Al₂(SO₄)₃, 2 gm; ZnSO₄, 2 gm; acetic acid, 4 ml; and distilled water, 90 ml. Dehydrate with dioxane, embed in paraffin and section at 10-20 μ. Stain with hematoxylin-eosin or with one of the following modifications of Van Gieson's formula: 1. 1% acid fuchsin, 10; picric acid (sat. aq.), 50; and 5% ZnSO₄, 40 volumes. 2. 1% acid fuchsin, 20; picric acid (sat. aq.), 80; and 5% CoSO₄, 40 volumes.

(2) The plastic mass consists of a 5-10% solution of Rhodopas (a vinyl copolymer) in acetone. Injection is made as with the oil mass except that a plastic squeeze-bottle and glass needle is preferable to a syringe. Indirect injection is used for both procedures, i.e., into the organ substance; not into a cannulated lymphatic vessel. After the plastic has hardened (24 hr), the unfixed tissue is subjected to corrosion by 5-10% NaOH in water.     

A Glutaraldehyde-Dichromate-Silver Sequence for Differentiating Norepinephrine Cells from Epinephrine Cells in Neonatal and Adult Rats—Paraffin Sections

A glutaraldehyde-K₂Cr₂O₇ procedure intensified by silver staining enabled norepinephrine and epinephrine cells to be distinguished readily in paraffin sections of the adrenal glands of rats 8 days after birth. The technique involved fixation in 0.1 M cacodylate-buffered 5% glutaraldehyde (6-24 hr), treatment with 3.5% K₂Cr₂O₇ (6-12 hr) and routine preparation of paraffin sections. The sections were deparaffinised, brought to water and immersed in Fontana's solution (24 hr), prepared by adding concentrated NH₄OH drop by drop to 5% AgNO₃ until the precipitate formed just redissolved; more 5% AgNO₃ was then added until a permanent cloudiness just developed. After a rinse in distilled water, the sections were treated with 0.5% gold chloride (5 min) and Na₂S₂O₃ (5 min), then mounted in Depex. This sequence resulted in an intense black cytoplasmic colouration in norpinephrine-containing cells of both the adult and 8-day-old animals whereas epinephrine-containing cells remained colourless. The glutaraldehyde-K₂CrO₇ procedure, without intensification, gave very clear results in the adult: a yellow cytoplasmic colour in the norepinephrine cells with epinephrine cells colourless. A glutaraldehyde-OsO₄ sequence gave a less well defined separation of these cell types in the adult and failed to distinguish the cell types in the neonate.     

DNA TURNOVER IN ADRENAL MEDULLARY CELLS OF DIFFERENT STRAINS OF RATS AND ITS ENHANCEMENT AFTER INTERMITTENT EXPOSURE TO COLD

In Italico and Wistar rats maintained at room temperature 1% of nuclei of cells in the adrenal medulla incorporate ³H-thymidine. Following intermittent exposure to cold, the numbers incorporating increase to 10% and 7% in Italico and Wistar strains respectively. Only in the Wistar strain does the increase occur during actual exposure.
Assuming S to be 6–8 hr the labelling indices actually determined indicate a turnover time of DNA of 21–29 days. Since mitotic indices in experimental and control animals were found to be 0.004% without colchicine treatment and 0.009% after 3 hr of colchicine treatment, the turnover times of cells were calculated to be 1388–3125 days. To correlate mitotic indices and labelling indices, an S period of 400 hr would have to be assumed. It is concluded therefore that: (i) most of the observed labelling of DNA is due to metabolic turnover of DNA and only a small proportion represents pre-mitotic synthesis, (ii) differences in the rates of DNA synthesis found during exposure to cold in Italico and Wistar rats respectively are sufficient to account for the differences in reduction of DNA previously found between the two strains under these experimental conditions.     

The effect of prolonged stress-inducing electrical stimulation on cell proliferation in rat palatal epithelium

Abstract. This study examines whether blocking of cell division by stress-inducing electrical stimulation can be maintained for a prolonged period of time and whether this results in the accumulation of a large number of cells ready to divide when the block is released.
A total of 96 rats was subjected to electrical stimulation at intervals of 30 min for periods of 2,4,6 or 12 hr. Groups of animals were killed every second hour during these stimulation periods. After 2, 4 and 6 hr groups of animals were exempted from further stimulation and killed 2 or 4 hr later. After termination of the 12 hr stimulation period, groups of animals were killed every second hour during the succeeding 24 hr. Forty-eight animals were left undisturbed and served as controls. Two and a half hours prior to death, each of the experimental and control animals was injected intraperitoneally (i.p.) with colchicine. Histological sections of the palatal mucosa were prepared and the numbers of arrested metaphases were counted.
The electrical stimulation for 2, 4, 6 and 12 hr consistently resulted in a reduced number of cells entering mitosis, indicating a blockade at the G₂/M transition. However, with an increase in the length of electrical stimulation, an increasing number of cells passed the block, while a decreasing number entered mitosis during the first 4 hr following cessation of the stimulation. The sum of metaphases accumulated during the various stress periods and the following 4 hr was always similar and consistently lower than the number of metaphases accumulated in the control animals within the same time periods. This observation indicates that, during stress-inducing electrical stimulation and the succeeding 4 hr, only a defined number of cells can enter the mitotic phase. Thus, in addition to the block at the G₂/M transition, there appears to be another block of cell division at an earlier stage in the cell cycle.     

Staining Mitochondria With Hematoxylin After Formalin-Sublimate Fixation; A Rapid Method

Mitochondria were stained in liver, kidney, pancreas, adrenal and intestinal mucosa of rat and mouse. Tissues 1 mm thick, were fixed in a mixture of saturated aqueous HgCl₂, 90 ml; formalin (37-38% HCHO), 10 ml, at room temperature (25°C) for 1 hr. Deparaffinized sections 3-4μ thick were treated with Lugol's iodine (U.S.P.) followed by Na₂S₂O₃ (5%), rinsed in water and the ribonucleic acid removed by any of the following procedures: 0.2 M McIlavaine's buffer, pH 7.0, 2 hr, or 0.2 M phosphate buffer, pH 7.0, 2 hr at 37°C; 0.1% aqueous ribonuclease, 2 hr at 37°C; 5% aqueous trichloracetic acid overnight at 37°C; or 1% KOH at room temperature for 1 hr. After washing in water, sections were treated with a saturated solution of ferric ammonium alum at 37°C for 8-12 hr and colored by Regaud's ripened hematoxylin for 18 hr. They were then differentiated in 1% ferric ammonium alum solution while under microscopic observation.     

Chromosome preparations from hepatocytes and bone marrow of Chinese hamsters: A direct method

This report describes a method for the direct preparation of chromosomes from the hepatocytes and bone marrow of the same Chinese hamster (Cricetulus griseus). The technique is a modification of that described by Becker et al. (J. natl. Ca. Inst. 46: 1261–69, 1971) for rat hepatocytes, with the following significant differences: (1) a less extensive partial hepatectomy is employed to initiate hepatocyte regeneration, (2) the use of a larger initial dose of colchicine (4 mg/K) 46–48 hours after hepatectomy instead of 1 mg/K 24 hours after hepatectomy, (3) the use of 0.075 M KCl as hypotonic solution instead of fetal calf serum diluted 1 : 7 with distilled water and (4) flame or blaze drying of chromosome preparations instead of air drying. The combination of the above modifications gave abundant, clear and well-spread chromosomes.     

Straight Oso4 versus Glutaraldehyde-Oso4 In Sequence as Fixatives for the Granular Vesicles in Sympathetic Axons of the Rat Pineal Body

Pineal bodies were removed immediately after death from 6 rats: representing both sexes, and adult and 21-day postnatal ages; cut into 2 or 3 pieces, and subjected to experimental fixations at pH 7.3, 0-4 C as follows: 1-2 hr in 1% OsO₄, with veronal-acetate buffer of phosphate buffer; 3-4 hr in 3% or 6% glutaraldehyde in 0.1 M or 0.2 M phosphate buffer, with or without 1% sucrose. Specimens from OsO₄ were dehydrated, and embedded in epoxy resin; those from glutaraldehyde were allowed to soak in buffer for 12-16 hr, then transferred to 1% OsO₄ at 0-4 C for 2 hr, and embedded in the same manner as the ones fixed directly in OsO₄. Representative electron micrographs of postganglionic sympathetic endings were studied for the morphology and frequency of granular vesicles. No consistent difference was shown between vesicles fixed in OsO₄ buffered by phosphate or by veronal-acetate, nor was there any effect caused by the different concentrations used for the glutaraldehyde solution; however, vesicles fixed by the glutaraldehyde-OsO₄ sequence showed an enhancement in the graininess of their membranes, were slightly larger, and had a much larger dense core than those fixed by OsO₄ alone. After glutaraldehyde-OsO₄, granular vesicles showed a frequency of 81%, whereas after direct fixation in OsO₄, only 40% without significant change their number per unit area. Therefore, glutaraldehyde-OsO₄ seems to be more effective than straight OsO₄ for the demonstration of granular vesicles in the autonomic nervous system.     

Colocalization of NO and VIP in neurons of the submucous plexus in the rat intestine

Since very few previous studies have carried out the quantitative analysis for the colocalization of nitric oxide (NO) and vasoactive intestinal peptide (VIP) in the submucous neurons in the rat digestive tract, we applied in vivo treatment of colchicine to enhance the immunoreactivity and examined the colocalization of NO synthase (nNOS) and VIP in neurons of the submucous plexus throughout the rat digestive tract. The density of nNOS-containing neurons in the submucous plexus in the stomach corpus (103±25 cells/cm², n=3) and that in the antrum (157±9 cells/cm², n=3) were significantly lower than those in small and large intestine. However no difference was detected in the cell density among duodenum (1967±188 cells/cm², n=3), jejunum (2640±140 cells/cm², n=3), ileum (2070±42 cells/cm², n=3), proximal colon (2243±138 cells/cm², n=3) and distal colon (2633±376 cells/cm², n=3). The proportion of nNOS-immunoreactive (IR), nNOS/VIP-IR and VIP-IR neurons to the total number of submucous neurons was examined. nNOS/VIP-IR neurons comprised 45–55% of total number of submucous neurons from the duodenum to the proximal colon, however those comprised 66.4±5.1% in the distal colon. The results showed that the dense distribution of nNOS-containing neurons was found in the submucous plexus throughout the small and large intestine, and large population of submucous neurons co-stored nNOS and VIP.     

Removal of Ribonucleic Acid from Bacterial Cells by Dilute Salt Solutions

Bacterial cells were impressed upon a clean glass slide, fixed in ethyl alcohol and immersed at 37°C in either of the following two salt solutions: (A) NaCl, 7.8 gm; KCl, 0.7 gm; distilled water, 1000 ml; adjusted to pH 7.0; or (B) 0.1M NaH₂PO₄, 400 ml; 0.1M Na₂HPO₄, 600 ml; KCl, 0.7 gm. After 1-5 hr soaking to remove ribonucleic acid, the slide was stained by Giemsa's method as usual. The staining revealed slender chromatinic bodies with reasonable clarity extending the whole diameter of the moderately swollen cell. The results of this method seemed to be much like those obtained after ribonuclease digestion.     

Staining of fresh, Undecalcified, thin Bone Sections

Fresh, undecalcified bone sections can be reproducibly and reliably stained by any of the following procedures: (A) Basic fuchsin, 1% in 30% alcohol, 48 hr, 22°C. (B) AgNO₃, 0.033 M, 48 hr, 22°C; washing 48 hr in a large volume of distilled water; exposure to light to develop the color. (C) Metallic sulfides (Co⁺⁺, Pb⁺⁺, Hg⁺⁺, Cu⁺⁺): the nitrate of the metal, 0.033 M, 48 hr, 22°C; then Na₂S, 0.033 M, 48 hr, 22° C. (D) Alizarin Red S, 0.1% solution in distilled water, 48 hr, 22°C; differentiated 48 hr at 22°C in weakly alkaline water, pH about 8. (E) KMnO₄: boiling 8-10 min in a 0.1 N, solution. With the exception of D the surface stain must be ground off the section for microscopic examination of its interior. Stain concentration, time and temperature can be altered to suit specific needs.     

Identification of presomitic mesoderm (PSM)-specific Mesp1 enhancer and generation of a PSM-specific Mesp1/Mesp2-null mouse using BAC-based rescue technology

Bacterial artificial chromosome (BAC) modification technology is a powerful method for the identification of enhancer sequences and genetic modifications. Using this method, we have analyzed the Mesp1 and/or Mesp2 enhancers and identified P1-PSME, a PSM-specific enhancer of Mesp1, which contains a T-box binding site similar to the previously identified P2-PSME. Hence, Mesp1 and Mesp2 use different enhancers for their PSM-specific expression. In addition, we find that these two genes also use distinct enhancers for their early mesodermal expression. Based on these results, we generated a PSM-specific Mesp1/Mesp2-null mouse by introducing a BAC clone, from which only early mesodermal Mesp1 expression is possible, into the Mesp1/Mesp2 double knockout (dKO) genetic background. This successfully rescued gastrulation defects due to the lack of the early mesoderm in the dKO mouse and we thereby obtained a PSM-specific Mesp1/Mesp2-null mouse showing a lack of segmented somites.