Detection of bromodeoxyuridine incorporation in mammalian chromosomes by a bromodeoxyuridine antibody

A commercially available bromodeoxyuridine (BrdUrd) antibody was used to demonstrate sister chromatid differentiation (SCD) and to evaluate sister chromatid exchanges (SCEs) in V79 Chinese hamster cells. V79 cells were cultivated for one cell cycle in the presence of BrdUrd, followed by a second cell cycle in the absence of BrdUrd. Chromosome preparations were stained by a common immunologic staining technique. The staining pattern observed is similar to that after FPG (fluorescent plus Giemsa) staining, though with reverse staining specificity. The sensitivity of BrdUrd detection is enhanced by a factor of 20 compared to the FPG technique and thus allows the evaluation of SCEs at very low BrdUrd concentrations. The application of the antibody technique gives information about the origin and localization of SCEs and produces further evidence for the spontaneous occurrence of SCEs.     

Reverse sister chromatid differential staining by Coomassie Brilliant Blue R-250

A sister chromatid differential staining pattern is observed if chromosomes replicate for two cycles in the presence of 5-bromodeoxyuridine (BUdR) and are subsequently stained in Hoechst 33258, irradiated with black light, and then stained in Coomassie Brilliant Blue R-250. In this pattern the chromatids containing DNA that is bifilarly substituted with BrdUrd are darkly stained and the chromatids with DNA that is unifilarly substituted are lightly stained. This staining pattern is the reverse of that found when slides are stained in Hoechst plus Giemsa. Slides stained with either Giemsa or Coomassie Blue can be destained and restained repeatedly with the other stain to alternate the pattern observed.     

Sister chromatid exchanges in Allium cepa

Differential staining of sister chromatids with Giemsa after BrdU incorporation into DNA was performed in Allium cepa L. chromosomes. A treatment solution containing 10^–7 M FdU, 10^–4 M BrdU and 10^–6 M Urd was found to ensure BrdU incorporation without affecting cell cycle duration. After several procedures before staining the slides with Giemsa had been tested, treatment with the fluorochrome compound 33258 Hoechst, exposure to UV light and heating at 55° C in 0.5×SSC, were found to be essential for good differentiation. The distribution of SCEs per chromosome agrees with the expected Poisson distribution. The mean value of SCEs per chromosome occurring when cells were exposed to the treatment solution for two consecutive rounds of replication (=5.5) was double the mean value observed when cells were exposed to the same treatment for only one round of replication (=2.8). SCEs were found to occur more frequently in those chromosome regions corresponding neither to C-bands nor to late replicating DNA-rich regions. Finally, the occurrence of SCEs involving less than the width of a chromatid is discussed.     

Reverse differential staining of sister chromatids after substitution with BUdR and incubation in sodium phosphate solution

Chinese hamster strain cells were cultured in the presence of BUdR and air-dried on slides. The chromosome preparations were incubated in 1 M NaH₂PO₄ at 88 °C for 4–6 min and stained with Giemsa. The reverse type of sister chromatid differential staining occurred, in which unifilarly BUdR-substituted chromatids stained faintly and bifilarly substituted chromatids stained darkly. Feulgen reaction performed on the same chromosomes after removing Giemsa stain showed the same type of differential staining.     

Two opposite types of sister chromatid differential staining in BUdR-substituted chromosomes using tetrasodium salt of EDTA

The direct staining of BUdR-substituted Chinese hamster chromosomes in a 4Na-EDTA-Giemsa solution resulted in a B-dark type of sister chromatid differential staining (SCD) in which bifilarly substituted chromatids stained dark. On the other hand, when BUdR-substituted chromosomes were pretreated with a 4Na-EDTA solution and then stained with Giemsa, a B-light type SCD was obtained in which bifilarly substituted chromatids stained light.     

Presence of a Base Line Level of Sister Chromatid Exchanges in Somatic Cells of DROSOPHILA MELANOGASTER IN VIVO and IN VITRO

Sister chromatid exchanges (SCEs) under in vivo and in vitro conditions were examined in ganglion cells of third-instar larvae of Drosophila melanogaster (Oregon-R). In the in vivo experiment, third-instar larvae were fed on synthetic media containing 5-bromo-2'-deoxyuridine (BrdUrd). After two cell cycles, ganglia were dissected and treated with colchicine. In the in vitro experiment, the ganglia were also incubated in media containing BrdUrd for two cell cycles, and treated with colchicine. SCEs were scored in metaphase stained with Hoechst 33258 plus Giemsa. The frequencies of SCEs stayed constant in the range of 25-150 micrograms/ml and 0.25-2.5 micrograms/ml of BrdUrd in vivo and in vitro, respectively. SCEs gradually increased at higher concentrations, strongly suggesting that at least a fraction of the detected SCEs are spontaneous. The constant levels of SCE frequency were estimated, on the average, at 0.103 per cell per two cell cycles for females and 0.101 for males in vivo and at 0.096 for females and 0.091 for males in vitro. No difference was found in the SCE frequency between sexes at any of the BrdUrd concentrations. The analysis for the distribution of SCEs within chromosomes revealed an extraordinarily high proportion of the SCEs at the junctions between euchromatin and heterochromatin; the remaining SCEs were preferentially localized in the euchromatic regions of the chromosomes and in the heterochromatic Y chromosome. These results were largely inconsistent with those of Gatti et al. (1979).     

Light and scanning electron microscopic observations on the two contrasting types of sister chromatid differential staining after ultraviolet light irradiation

Chinese hamster cells were grown with 50 M 5-bromodeoxyuridine (BrdU) during the penultimate S phase to obtain chromosomes with the TB-TT chromatid constitution. Chromosome preparations made by the air-drying method were used to study the sister chromatid differential staining (SCD) resulting from ultraviolet (UV) irradiation followed by Giemsa staining by light and scanning electron microscopy (SEM). When chromosomes irradiated with UV light (253.7 nm, 5.2 J/m²/s) for more than 5 h were stained with 1% to 4% Giemsa in phosphate buffered saline (PBS) or in distilled water, the resulting SCD invariably belonged to the B-light type in which the TB-chromatid stained lightly. SEM observations of these chromosomes suggested that the B-light SCD was due to the selective photolysis of the TB-chromatid. On the other hand, when chromosomes were irradiated for only 10 min, and stained with 1% Giemsa in PBS, they showed a B-dark type SCD in which the TB-chromatid stained darkly. However, when chromosomes irradiated for 10 min were stained with 4% Giemsa in PBS or 1% Giemsa in distilled water, the resulting SCD again belonged to the B-light type. These findings indicate that when the irradiation dose is small, the resultant SCD is not a simple reflection of selective photolysis in the TB-chromatids and the type of SCD depends not only on the concentration of Giemsa but also on the salinity of the staining solution.     

Staining human lymphocytes and onion root cell nuclei with madder root.

We performed staining experiments on cells using natural dyes and different mordants using techniques that are used for wool and silk dyeing. The natural dye sources were madder root, daisy, corn cockle and yellow weed. Ferrous sulfate, copper sulfate, potassium tartrate, urea, potassium aluminum sulfate and potassium dichromate were used as mordants. Distilled water, distilled water plus ethanol, heptane, and distilled water plus methanol were used as solvents. All dye-mordant-solvent combinations were studied at pH 2.4, 3.2 and 4.2. The generic staining procedure was to boil 5-10 onion roots or stimulated human lymphocyte (SHL) preparations in a dye bath on a hot plate. Cells were examined at every half hour. For multicolor staining, madder-dyed lymphocytes were decolorized, then stained with Giemsa. The AgNOR technique was performed following the decolorization of Giemsa stained lymphocytes. Good results were obtained for both onion root cells and lymphocytes that were boiled for 3 h in a dye bath that included 4 g madder root, 4 g ferrous sulfate as mordant in 50 ml of 1:1 (v/v) methanol:distilled water. The pH was adjusted to 4.2 with 6 ml acetic acid. We conclude that madder root has potential as an alternative dye for staining biological materials.     

The effect of continuous gamma irradiation on formation of sister chromatid exchanges (SCEs) and chromosomal aberrations in meristematic cells ofVicia faba

Germinated seeds ofVicia faba were continuously irradiated at low dose rate of gamma rays (0.05 Gy h-¹) up to a total accumulated dose of 2 Gy. The FPG (fluorescence plus Giemsa) technique of differential chromatid staining was used to monitor the frequency of sister chromatid exchanges (SCEs) in irradiated root tip meristem cells. The results of the experiments have demonstrated that SCE frequency is raised by continuous gamma irradiation only in plant cells containing BrdU in the chromosomal DNA. No effect concerning SCE formation was recorded at continuous irradiation of meristematic cells of Vicia faba with native, i. e. BrdU-nonsubstituted, DNA. In contrast to SCEs, a significant increase was found in the yield of chromosomal aberrations in all variants of irradiation.     

Staining human lymphocytes and onion root cell nuclei with madder root

We performed staining experiments on cells using natural dyes and different mordants using techniques that are used for wool and silk dyeing. The natural dye sources were madder root, daisy, corn cockle and yellow weed. Ferrous sulfate, copper sulfate, potassium tartrate, urea, potassium aluminum sulfate and potassium dichromate were used as mordants. Distilled water, distilled water plus ethanol, heptane, and distilled water plus methanol were used as solvents. All dye-mordant-solvent combinations were studied at pH 2.4, 3.2 and 4.2. The generic staining procedure was to boil 5–10 onion roots or stimulated human lymphocyte (SHL) preparations in a dye bath on a hot plate. Cells were examined at every half hour. For multicolor staining, madder-dyed lymphocytes were decolorized, then stained with Giemsa. The AgNOR technique was performed following the decolorization of Giemsa stained lymphocytes. Good results were obtained for both onion root cells and lymphocytes that were boiled for 3 h in a dye bath that included 4 g madder root, 4 g ferrous sulfate as mordant in 50 ml of 1:1 (v/v) methanol:distilled water. The pH was adjusted to 4.2 with 6 ml acetic acid. We conclude that madder root has potential as an alternative dye for staining biological materials.     

Influence of low doses of BrdU and estimation of spontaneous SCE in CHO chromosomes: three-way differential staining and an immunoperoxidase method

The influence of low doses of 5-bromodeoxyuridine (BrdU) on the occurrence of sister chromatid exchanges (SCEs) during the first cell cycle, when unsubstituted DNA templates replicate in the presence of the halogenated nucleoside (SCE1) has been assessed in third mitosis (M3) Chinese hamster ovary (CHO) cells showing three-way differential (TWD) staining. In addition, lower concentrations of BrdU, not detectable by Giemsa staining, have been tested by a high resolution immunoperoxidase method (anti-BrdU monoclonal antibody) and SCEs were scored in second mitosis (M2) cells. Our findings was a dose-response curve for SCE1 that allows an estimated mean spontaneous yield of 1.32/cell per cell cycle by extrapolation to zero concentration of BrdU. On the other hand, when the total SCE frequency corresponding to the first and second rounds of replication (SCE1+SCE2) found in M3 chromosomes was compared with the yield of SCEs scored in M2 cells grown in BrdU at doses lower than 1 M no further reduction was achieved. This seems to indicate that SCEs can occur spontaneously in this cell line, though the estimated frequency is higher than that reported in vivo.by S. Wolff     

Three-way differential staining of sister chromatids in M3 chromosomes : Evidence for spontaneous sister chromatid exchanges in vitro

Three types of Giemsa differential staining of sister chromatids were observed in HeLa cells when they were exposed continuously to 5-bromodeoxyuridine (BrdUrd) for three replication cycles. In type-1, about a half set of chromosome complements were composed of pairs of darkly-stained and intermediately-stained chromatids; the other half consisted of pairs of intermediately-stained and lightly-stained chromatids. In type-2, one fourth of chromatids was stained darkly and the remaining ones were stained lightly. In type-3, about a half set of chromosomes consisted of the pairs of darkly-stained and lightly-stained chromatids and the rest of pairs of intermediately-stained and lightly-stained chromatids. Cells showing each differentiation pattern at the third mitotic phase were dependent on the stages of the first DNA synthetic (S) phase at which BrdUrd treatments were initiated. Type-1 cells were observed, when BrdUrd treatment was initiated anywhere from G1 to early S phase, type-2 when treatments were begun in middle S stage, and type-3 when treatments were initiated in the late stages of the first S phase. The appearance of the three types seems to be caused by a different amount of BrdUrd incorporated into DNA between the first (S1) and the second S period (S2). The amount of BrdUrd incorporated is as follows: in type-1 S1>S2, in type-2 S1 S2 and in type-3 S2>S1.By analysing type-1 cells, all of the sister chromatid exchanges (SCEs) occurring during each replication cycle can be accurately counted and distinguished from one another. In cells exposed to BrdUrd above 5 μg/ml, the frequencies of SCEs occurring during S1, S2, and S3 are higher than those detected at lower BrdUrd concentrations. On the other hand, at lower concentrations (0.1–1.0 μg/ml) they occurred at the same frequency during S1, S2, and S3. Thus, SCEs detected at low concentrations are free from the incremental effect of BrdUrd incorporated, and enable us to estimate the spontaneous level of SCE frequency.     

Staining the Nucleus in Yeasts

Yeast cells kept young by repeated subculturing were centrifuged, washed twice in distilled water and smeared on slides coated with a little egg albumen. The cells were treated with 0.002 M 8-hydroxyquinoline for 1 hr, fixed first in OsO, vapour for 30 sec and then in chloroform for 30 sec. The slides were passed through descending grades of alcohol, washed in distilled water, then immersed in 0.17 M NaCl solution for 2 hr. at 57°C. They were again washed in distilled water and later hydrolysed in 1 N HCl at 60°C for 5-7 min. This was followed by washing in distilled water and in buffer. The slides were then kept for 3 hr in Giemsa stain comprising 96 ml of phosphate buffer of pH 7.0 and 4 ml of the stain. After dehydration, mounting was done in balsam. Nuclei were brightly stained and well differentiated; centrosomes were clear, and the process of nuclear division and movement to daughter cells could be studied. Pretreatment with 8-hydroxyquinoline increased the viscosity of the cytoplasm, while NaCl treatment and acid hydrolysis led to the complete removal of ribonucleic acid and basophilic material. A selective staining of chromatin was thus achieved. Structures resembling chromosomes could be seen when fixed and stained cells were squashed, soon after the removal of the slides from the stain, under a cover glass by applying uniform pressure with a rubber stopper. Fixation in osmic acid vapor and chloroform followed by acid hydrolysis and staining in leucobasic fuchsin also helps to obtain bright staining of the nucleus; however, the preparations are inferior to those obtained after 8-hydroxyquinoline, NaCl treatment and Giemsa staining.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40° C is recommended for stallion semen.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa.

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2-4 h Giemsa staining at 25-40 degrees C is recommended for stallion semen.     

Romanowsky-Type Staining: Effect of Adding Acid Dyes, Particularly Chromotrope 2R

Nuclear staining can be depressed and nucleolar staining accentuated by the addition of 1 part of 1% chromotrope 2R to 9 parts of Gurr's Improved Giemsa R66; this mixture then being diluted -with an equal quantity of distilled water and allowed to stand for 0.5-1 hr before use. Methanol-fixed smears of Walker rat carcinoma, used as test material, were stained 5 min. Experiments with undiluted and diluted Giemsa indicate that ionisation of the azure-eosin complex is necessary for the development of the metachromatic red nuclear color of Romanowsky-type staining. It is suggested that chromotrope 2R depresses this ionisation.     

Viability and acrosome staining of stallion spermatozoa by Chicago sky blue and Giemsa

A simple trypan blue-neutral red-Giemsa staining procedure for simultaneous evaluation of acrosome, sperm head, and tail membrane integrity and morphology has been used to evaluate equine spermatozoa. Some special characteristics and problems have arisen in evaluating stallion semen. One problem was the differentiation of intact vs. damaged sperm tails primarily in frozen and thawed samples. After freezing and thawing, a high percentage of spermatozoa with an unstained head and stained tail were observed. These cells are considered immotile. Therefore, unambiguous differentiation of intact vs. damaged sperm tail membrane is very important for evaluating semen quality. The aim of our study was to develop a method especially for stallion sperm to distinguish more accurately the different cell types. We compared Chicago sky blue 6B (CSB) to trypan blue (TB) for viability staining. CSB/Giemsa staining showed good repeatability and agreement with TB/Giemsa measurements. For densitometry analysis, individual digital images were taken from smears stained by CSB/Giemsa and by TB/Giemsa. A red-green-blue (RGB) histogram for each area of spermatozoa was drawn. Differences of means of RGB values of live vs. dead tails and separate live vs. dead heads from each photo were used to compare the two staining procedures. CSB produced similar live/dead sperm head differentiation and better tail differentiation. TB can be replaced by CSB and this results in more reliable evaluation. After staining with 0.16% CSB and 4 min fixation, 2–4 h Giemsa staining at 25–40° C is recommended for stallion semen.     

Analysis by reflection. A new method of observing human chromosomes

When metaphase preparations of human cells are stained with Giemsa and submitted to epi-illumination with white light a brilliant yellow-green reflexion from the chromosomes is produced, quite comparable to fluorescence after acridine orange staining. Beside a remarkable stability of the image during repeated observations, this method yields excellent resolution.     

Differential giemsa staining of sister chromatids after extraction with acids

Chromosomes of Chinese hamster strain cells were air-dried on slides after BrdU substitution for two or three rounds of replication. The preparations were treated with 20% PCA at 55 degrees C for 20-30 min, or 5N HCl at 55 degrees C for 15-20 min. After staining with Giemsa, unifilarly BrdU-substituted chromatids stained faintly and bifilarly substituted chromatids stained darkly. Such a pattern of sister chromatid differential staining was confirmed by the examination of metaphase cells grown with BrdU for three rounds of replication.     

'Glowing' chromosomes in cells undergoing rapid division

Previous investigations in which metaphase plates of cells in rapid division were incubated in phosphate buffer at high temperature revealed numerous heterochromatic dots in chromosomes after Giemsa staining. In contrast, chromosomes from cells with a reduced capacity for reproduction were devoid of such dots, or the dots were sloughed-off into rings and patches of heterochromatin. In two types of cells which were rapidly dividing, namely HeLa cells (cervical cancer) and cells from regenerating planaria, phosphate incubation followed by Giemsa staining revealed an 'aura' or 'glowing' effect on the chromosomes, consisting of a densely staining core surrounded by a lightly stained periphery. This finding might be developed into a diagnostic test for certain malignancies, for cells undergoing dedifferentiation, or for tissues undergoing regeneration.