On the mechanism of differential Giemsa staining of bromodeoxyuridine-substituted chromosomes

Summary Experiments were performed to find out whether different mechanisms are involved in FPG-(fluorescent plus Giemsa) staining for the demonstration of replication patterns and sister chromatid differentiation (SCD) after bromodeoxyuridine (BrdU)-substitution of V79 Chinese hamster chromosomes. The influence of variations of the staining procedure on the quality of both SCD and replication patterns was comparatively investigated and differences in the demonstration of these two phenomena within the same chromosome were studied using various BrdU-labeling protocols. The results show that at least graduated differences exist. For a good differentiation of replication patterns a stronger FPG-treatment is necessary than it is for SCD. Partial BrdU substitution only leads to replication patterns in the next mitosis. A further round of replication either in the presence or absence of BrdU causes a reduced staining of the complete chromatid and three-way differentiation is seen in third generation mitoses. These results support the view that alterations of chromosomal proteins during BrdU-incorporation and replication of BrdU-substituted DNA are decisive for differential staining.     

Considerations on the mechanism of differential Giemsa staining of BrdU-substituted chromosomes

Summary The staining properties of unifilarly bromodeoxyuridine (BrdU)-substituted chromatids were compared using fluorescent-plus-Giemsa (FPG) staining methods. It was found that the staining intensity of chromatids which had incorporated BrdU in the next to last S-phase is less than that of chromatids whose BrdU-containing strand came from the last cell cycle. Thus, FPG-staining is not a function of the number of BrdU-substituted DNA strands alone. These findings lead to the conclusion that the primary point of action of PFG staining leading to sister chromatid differentiation (SCD) are chromosomal proteins which have been altered in the replication of BrdU-substituted DNA and that the demonstration of the SCD and replication patterns with the same staining procedure is based on different mechanisms.     

Demonstration of sister chromatid differentiation in human amniotic fluid cells after partial synchronization with BrdU or dT surplus

Summary Protocols are compared demonstrating sister chromatid differentiation (SCD) in human amniotic fluid (AF) cells with and without partial synchronization. Partial synchronization both with an excess of 5-bromodeoxyuridine (BrdU) and an excess of thymidine leads to an increase of metaphases with SCD. Compared with unsynchronized cells, the rate of sister chromatid exchanges (SCE) is not increased. Studies on the late replicating X chromosome of female cells showed that the addition of mitomycin C (MMC) after releasing the thymidine block preferentially induces SCEs in late replicating regions. The partial synchronization with thymidine surplus provides a good basis for SCE experiments with AF cells and facilitates the prenatal diagnosis of diseases characterized by changes in the SCE rate.     

Analysis of low concentrations of 5-bromo-2-deoxyuridine on sister chromatid exchanges in human lymphocytes

To determine a concentration of 5-bromo-2-deoxyuridine (BrdU) sufficient for sister chromatid differentiation (SCD), and yet having a minimal effect on the number of sister chromatid exchanges (SCEs), we assessed the effect produced on the number of SCEs by low concentrations (1, 3, and 10 micrograms/mL) of BrdU. SCD was not obtained in 19% of the 31 subjects with 1 microgram/mL of BrdU, while the differentiation was adequate for all samples treated with 3 and 10 micrograms/mL. We statistically analysed the effects of these three different doses and found no significant difference in the number of SCEs obtained with the doses of 1 and 3 micrograms/mL, but a significant difference was observed between these two concentrations and 10 micrograms/mL. We therefore suggest that the dose of 3 micrograms/mL, while sufficient to produce reliable differential staining, still permits an adequate evaluation of the base line of SCEs and appears to enhance the sensitivity of the test to evaluate between-individual variations. Our experiments also underline that SCE counts should include the centromere exchanges.     

Induction of endoreduplication by hydrazine in Chinese hamster V 79 cells and reduced incidence of sister chromatid exchanges in endoreduplicated mitoses

Hydrazine in high concentrations very effectively induces endoreduplication in Chinese hamster V 79 cells. The addition of 5-bromodeoxyuridine (BrdU) for the duration of one cell cycle prior to the induction of endoreduplication produces diplochromosomes with sister chromatid differentiation (SCD) after differential chromatid staining. The fact that diplochromosomes with complete SCD are obtained shows that endoreduplication was induced in cells that were in G2-phase. The analysis of sister chromatid exchanges (SCEs) showed that hydrazine treatment rarely led to increased SCE frequencies in mitoses after endoreduplication, but that it caused a strong SCE induction in diploid second division metaphases in the same culture. Neither catalase nor cysteine had an effect on the induction of endoreduplication or the incidence of SCEs. Treatment of the cells with mitomycin C prior to addition of BrdU led to increased SCE frequencies. Compared with the normal mitoses from the same preparation, the mitoses after endoreduplication showed a significantly reduced induction of SCEs. In contrast to these findings, SCE induction was not reduced in the common tetraploid V 79 cells after colcemid-induced polyploidization.     

Sister chromatid differentiation and chromosomal in situ suppression hybridization: a combined methodology for analyzing cell proliferation and SCEs in individual chromosomes.

A technique combining sister chromatid differentiation (SCD) with chromosomal in situ suppression (CISS) hybridization is described. This combined methodology allows simultaneous analysis of cell-proliferation kinetics and sister chromatid exchanges (SCEs) in chromosomes identified by probes. To demonstrate the usefulness of this approach, cultured fibroblasts from a patient with Pallister-Killian syndrome, mos46/47,+i(12p), a chromosome mosaicism disorder, were studied. The fibroblasts were cultured in the presence of 5-bromodeoxyuridine (BrdU) for 72 h. Chromosome preparations were stained by a modified fluorescence-plus-Giemsa method to obtain SCD. For identification of the normal chromosome 12 and the i(12p), CISS hybridization with a biotin-labeled chromosome 12-specific library probe (LA 12NS01) was carried out after SCD. The hybridization was detected by an indirect immunofluorescence technique. For the analysis of cell kinetics and SCEs, the technique allows rapid, reliable identification of abnormal and normal cell populations. It also allows analysis of SCEs in individual chromosomes.     

Sister chromatid exchange in highly purified human B and T lymphocytes

Summary Sister chromatid exchange (SCE) rates were determined in human peripheral blood B and T lymphocyte populations highly purified by immunologic methods. The purified populations were supplemented with -irradiated unseparated autologous mononuclear cells to restore helper-functions and stimulated with pokeweed mitogen (PWM) and phytohemagglutinin (PHA), respectively. Measured at the different peaks of proliferation after identical bromodeoxyuridine (BrdU) incubation times, T lymphocytes showed significantly higher SCE frequencies than B lymphocytes. In both populations, different proliferation kinetics and a different minimal BrdU concentration for sister chromatid differentiation (SCD) were observed.     

In vivo BrdU-33258 Hoechst analysis of DNA replication kinetics and sister chromatid exchange formation in mouse somatic and meiotic cells

BrdU (5-bromodeoxyuridine)-33258 Hoechst methods have been adapted for in vivo analyses of replication kinetics, sister chromatid differentiation and sister chromatid exchange (SCE) formation in mice. Sufficient in vivo BrdU substitution for cytological detection was effected with multiple intraperitoneal injections of the analogue. The combination of centromere staining asymmetry and sister chromatid differentiation at metaphase permits unambiguous determination of the number of replications in BrdU and dT (deoxythymidine) undergone by individual cells. Late-replicating regions in marrow and spermatogonial chromosomes are highlighted by bright fluorescence after sequential incorporation of BrdU followed by dT during a single DNA synthesis period. SCEs are analyzed in marrow and spermatogonial metaphases after successive complete cycles of BrdU and dT incorporation. Significant induction of SCE was observed with both mitomycin C and cyclophosphamide; the latter drug requires host-mediated activation to be effective. In meiotic metaphase cells harvested two weeks after BrdU incorporation, satellite DNA asymmetry, sister chromatid differentiation and SCE could be detected in a few chromosomes, most frequently the X and the Y.     

Differential fluorescence of sister chromatids in chicken embryos exposed to 5-bromodeoxyuridine

Differential fluorescence of sister chromatids (SCD) and sister chromatid exchanges (SCE) were visualized in chromosomes obtained directly from growing chicken embryos. SCD was obtained by exposing 3-day embryos to BrdU (12.5-50 mug) in ovo for 26 hours and staining air dried chromosome preparations with 33258 Hoechst. Bright, stable fluorescence and continued SCD were achieved if slides were mounted in McIlvaine's pH 4.4 buffer. Embryo growth, mitotic activity and gross chromosome morphology were not adversely altered by the BrdU treatments. The SCE rate was estimated to be 0.07 SCEs per macrochromosome and 0.75 SCEs per metaphase for two cell cycles.     

Three-way differentiation of sister chromatids in endoreduplicated (M3) chromosomes of Bloom syndrome B-lymphoid cell line

Summary The three-way differentiation of sister chromatids (3-way SCD) in M₃ endoreduplicated chromosomes in a Bloom syndrome (BS) B-lymphoid cell line, suggested that in addition to exchanges between sister chromatids (intra-exchanges), non-sister chromatid exchanges (inter-exchanges) also occur, especially in BS high SCE cells. In BS diploid chromosomes such inter-exchanges probably get confused with intra-exchanges when total SCEs are accounted for. Bloom syndrome high SCE cells probably do not follow the same bromodeoxyuridine (BrdU) uptake pattern over three cell cycles as normal cells. The 3-way SCD in M₃ endoreduplicated chromosomes can be explained on the basis of Schvartzman's second model (1979) as well as Miller's model (1976), depending on the pattern of uptake of BrdU over three cell cycles. An interference in the previous events of exchanges in the following cell cycle (i.e., cancellation of SCEs) in BS chromosomes was observed in some regions, though not in high numbers.     

Bromodeoxyuridine tablet methodology for in vivo studies of DNA synthesis.

5-Bromodeoxyuridine (BrdU) tablets with different physical characteristics are useful in a wide variety of studies requiring detection of DNA replication in vivo. These tablets can effect a high substitution of BrdU in DNA, thereby permitting sister chromatid differentiation in chromosomes stained with 33258 Hoechst alone or in conjunction with Giemsa. Baseline and cyclophosphamide-induced in vivo sister chromatid exchange frequencies in mouse spleen, marrow, and thymus were measured and found to be significantly greater than those in spermatogonia. Sister chromatid exchange analysis was also extended to mouse liver and to Chinese hamster and Armenian hamster marrow cells. Sister chromatid differentiation was observed in Armenian hamster meiotic tissue, and evidence for interhomolog chromatid exchange obtained.     

Sister chromatid differentiation and isolabeling of chromosomes

Summary Isolabeling observed during sister chromatid differentiation (SCD) was studied from human skin fibroblasts by the fluorescence-plus-Giemsa (FPG) technique. Bromodeoxyuridine (BrdU) was fed to exponentially dividing cells for 52 h to enable completion of two consecutive cycles of DNA replication. During this period, the late-replicating regions of some chromosomes were able to go through three replication cycles. These chromosome regions had evidently incorporated BrdU bifiliarly in both chromatids and hence, on staining with FPG, appeared isostained (isolabeled). Thus, incubation of exponentially dividing cells with BrdU for a period longer than that required for two cell cycles appears to be a suitable method for revealing the late-replicating regions of the genome, such as the X chromosome in a human female, as isolated.In another experiment with Indian muntjac chromosomes, isolabeled segments were darkly stained, which suggested unifilar incorporation of BrdU. In this case, unequal crossing-over or an unequal distribution of thymine residues probably is responsible for the isolabel.     

Characterization of mitoses with sister chromatid differentiation (SCD) and consequences for the analysis of proliferation kinetics and sister chromatid exchanges in asynchronously growing cells

Summary Labeling cells with bromodeoxyuridine (BrdU) permits the differentiation of mitoses of the first, second, and third generation after the addition of BrdU. The term second mitoses is used for those cells which have incorporated BrdU for two-S-phases and which exhibit sister chromatid differentiation (SCD). However, SCD can also be obtained if the cell was in S-phase at the time of BrdU-addition and had already replicated part of its DNA. Such cells with incomplete BrdU-substitution in the first S-phase can only be differentiated from completely substituted ones by the quality of the SCD and are usually also grouped as second mitoses in the evaluation of experiments. Due to the heterogeneity of the evaluated second mitoses, the determination of proliferation delay and the incidence of sister chromatid exchange-induction can depend on the time of chromosome preparation.     

Rapid irradiation procedure for obtaining permanent differential staining of sister chromatids and aspects of its underlying mechanism

Summary When fixed metaphase preparations of lymphocytes cultured in the presence of BrdU during two cell cycles are subjected to a 1-min simple irradiation treatment with near-ultraviolet light (radiation dose 3×10⁵ J/m²), subsequent Giemsa staining produces differential staining of sister chromatids irrespective of previous exposure to a photosensitizer. The effects of this procedure were analyzed by irradiating single metaphases under the microscope, thus allowing precise dosage of radiation: Metaphase were subsequently stained with Giemsa and then subjected to the Feulgen-Schiff procedure. Whereas in the presence of DAPI as a photosensitizer a differential breakdown of BrdU-containing DNA in the chromatids under the influence of irradiation appeared to be the cause of sister chromatid differentiation, alterations presumably in the higher oeder structure of chromatin, not accompanied by removal of DNA, induced sister chromatid differentiation without DAPI.     

Involvement of sulfhydryl groups of chromosomal proteins in sister chromatid differentiation

The fluorescence of human lymphocyte chromosomes stained with sulfhydryl group-specific fluorochromes is markedly enhanced by a mild near-ultraviolet irradiation pretreatment, indicating breakage of protein disulfide bonds. When metaphase preparations of cells cultured in the presence of BrdU during two cell cycles are irradiated and subsequently stained with the sulfhydryl group-specific fluorescent reagents used in this study, a differential fluorescence of sister chromatids is observed. After staining with the DNA-specific fluorochrome DAPI an opposite pattern of lateral differentiation appears. It can be concluded that the chromatid containing bifilarly BrdU-substituted DNA has a higher content of sulfhydryl groups than the chromatid containing unifilarly BrdU-substituted DNA. This implies a more pronounced effect of breakage of disulfide bonds in the chromatid with the higher degree of BrdU-substitution. BrdU-containing chromosomes pretreated with the mild near-ultraviolet irradiation procedure used by us, do not show any differentiation of sister chromatids after Feulgen staining. Using sulfhydryl group-specific reagents, differential fluorescence of sister chromatids could still be induced by irradiation with near-ultraviolet light after the complete removal of DNA from the chromosomes by incubation with DNase I. Thus, the protein effect of irradiation of BrdU-containing chromosomes takes place independently of what occurs to DNA.Our results indicate that subsequent to the primary alteration of chromatin structure caused by the incorporation of BrdU into DNA, breakage of disulfide bonds of chromosomal proteins might play an important role in bringing about differential staining of sister chromatids, at least for those procedures that use irradiation as a pretreatment or prolonged illumination during microscopic examination.     

The fragile site (16)(q22)

Summary In the lymphocytes of heterozygous carriers of the rare autosomal fragile site (16)(q22) an exceptionally high frequency of sister chromatid exchanges was demonstrated at the induced fragile site by means of simultaneous berenil and BrdU treatment of the cultures. The rate of sister chromatid exchanges at q22 is also increased in the fragile chromosome 16 by treating the cells with BrdU alone. The possible reasons for the preferential occurrence of induced and spontaneous sister chromatid exchanges at fra (16)(q22) are discussed.     

Sister chromatid exchange in the Mongolian gerbil, Meriones unguiculatus

Sister chromatid exchange (SCE) studies have been performed in a variety of animals, both in vitro and in vivo, as well as in plants. To date, no such studies have been performed in any member of the gerbil sub-family (Gerbillinae). A new sister chromatid differential staining method was used with mice in vivo and has now been applied to the Mongolian gerbil, Meriones unguiculatus. With some modifications, this in vivo method was found to be highly reproducible in gerbils, and had consistently produced many metaphase cells with clear sister chromatid differentiation. The method involves subcutaneous implantation of a 50 mg slow-release BrdU pellet, the fluorochrome Hoechst 33258, phosphate buffering at pH 6.8, and incandescent light exposure.     

A high resolution study of the DNA replication patterns of Chinese hamster chromosomes using sister chromatid differential staining technique

Chinese hamster cells were grown for 1+ and 2+ cell cycles in the presence of BrdU and then treated by the sister chromatid differential staining technique (SCD). Those regions of a chromosome which had replicated twice in the presence of BrdU were pale staining and by selecting appropriate metaphase cells an accurate reconstruction of the DNA synthetic patterns was possible. A direct correlation between the staining intensity of the G bands and the order in which they replicate was found. Dark staining G bands were always the last region of a chromosome to replicate while G negative bands were first. It is concluded that each G band may be a cluster of replicons capable of initiating DNA synthesis simultaneously.     

Sister chromatid differentiation and exchanges in adult mudminnows (Umbra limi) after in vivo exposure to 5-bromodeoxyuridine

An in vivo system for the detection of sister chromatid exchange (SCE) in the central mudminnow, Umbra limi, is presented. Sister chromatid differential (SCD) and SCE were demonstrated by fluorescent and Giemsa procedures 5 to 6 days after the fish were injected with 500 g/g of BrdU. The exchange rate was found to be 2.64 SCEs metaphase in the intestines and 2.42 SCEs/metaphase in the gills. SCE analysis in U. limi should be a useful tool for measuring the mutagenicity of water-borne chemicals.     

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.