Asymmetric decondensation of the L cell heterochromatin by Hoechst 33258

A benzimidazole derivative, Hoechst 33258 can induce decondensation of constitutive heterochromatin in the mouse derived L cell chromosomes when the compound is given in sufficiently high concentration (40 micrograms/ml) to the L cell culture. Hoechst 33258 at low concentration (1 micrograms/ml, 16 h) cannot produce this effect on L cell chromosomes. Bromodeoxyuridine (BUdR) incorporation for one cell cycle simultaneous with the Hoechst 33258 treatment at low concentration could decondense heterochromatin segments in metaphase chromosomes. The heterochromatin decondensation, however, was asymmetric; it was observed only on one chromatid and the other of a chromosome remained in condensed state. The observation of asymmetric decondensation of heterochromatin by Hoechst 33258 after BUdR incorporation for one cell cycle, the association of A-T rich satellite DNA to mouse heterochromatin, and available data on the specific binding of Hoechst 33258 to A-T base pairs of DNA and on the higher affinity of the compound to BUdR substituted DNA than to ordinary DNA implied that the binding of Hoechst 33258 molecules to A-T rich satellite DNA is the cause of heterochromatin decondensation.     

A bromodeoxyuridine (BUdR)-mithramycin technique for detecting cycling and non-cycling cells by flow microfluorometry

Bromodeoxyuridine (BUdR) incorporation into cellular DNA results in an increase in fluorescence of mithramycin-stained cells. Flow microfluorometry can be used to distinguish among cells which have not replicated, cells which have replicated once, and cells which have replicated two or more times in the presence of 30 μM BUdR. This technique offers two advantages over present protocols: (1) a positive fluorescent signal is provided by the mithramycin stain rather than a negative signal, as with the Hoechst stain; (2) after mithramycin staining, hundreds of thousands of cells in any phase of the cell cycle can be analyzed in less than 10 min. The BUdR-mithramycin technique described herein is a useful tool for studying the cell-cycle kinetics of heterogeneous populations containing dividing and non-dividing cells.     

Effects of 5-bromodeoxyuridine on metamorphosis and on cell cycle kinetics of ganglion cells in Drosophila melanogaster

In order to determine suitable experimental conditions for estimating the accurate spontaneous frequency of sister chromatid exchanges (SCEs) in vivo in somatic cells of Drosophila melanogaster, the effects of bromodeoxyuridine (BUdR) on metamorphosis as well as on cell cycle kinetics were examined. The rate of growth of third-instar larvae, fed on BUdR-containing synthetic medium, markedly delayed with increasing concentrations of BUdR, but this toxic effect of BUdR was not observed below 150 μg/ml.Furthermore, the rate of eclosion drastically decreased by the incorporation of BUdR: it was reduced to about one-half of that in the control when the larvae were exposed to 100 (μg/ml. On the other hand, little difference in the rate of pupation was found within the range of 0–800 μg/ml BUdR. These results indicate that the developmental stage from pupa to adult is the most sensitive phase to BUdR.To test the effect of BUdR on cell cycle, metaphase cells were classified as having undergone each replication cycle in the presence of different BUdR concentrations according to the pattern of differential staining of sister chromatids, and the proportion of each replication cycle cells examined. No inhibition of cellular kinetics was observed at BUdR concentrations below 200 μg/ml.On the basis of these results, 100 μg/ml was chosen as suitable BUdR concentration for the analysis of cell cycle kinetics and according to the distribution of replication cycle metaphase cells as a function of time after the initiation of BUdR treatment, the cell cycle duration of the third-instar larval ganglion cells was roughly estimated to be about 7–8 h, at least under our experimental conditions.     

Flow cytometric cell cycle analysis using the quenching of 33258 Hoechst fluorescence by bromodeoxyuridine incorporation.

Cultures of L cells were grown in medium containing 2.0 mg/l bromodeoxyuridine (BUdR) and stained with the fluorescent dye 33258 Hoechst for flow cytometric analysis. During exposure to BUdR, The cells replace thymidine by BUdR in the newly synthesized DNA. The new DNA is not stainable with 33258 Hoechst, which is highly specific for thymidine. The temporal development of the fluorescence distributions after addition of BUdR to the growth medium has been investigated in the flow cytometer, and the data were used to calculate the mean durations of the phases G1, S and G2 + M in exponentially growing cultures as well as the cycle transit times in synchronized cultures. The percentage of non-cycling cells was determined in each experiment.     

FLOW CYTOMETRIC CELL CYCLE ANALYSIS USING THE QUENCHING OF 33258 HOECHST FLUORESCENCE BY BROMODEOXYURIDINE INCORPORATION

Cultures of L cells were grown in medium containing 2.0 mg/l bromodeoxyuridine (BUdR) and stained with the fluorescent dye 33258 Hoechst for flow cytometric analysis. During exposure to BUdR, the cells replace thymidine by BUdR in the newly synthesized DNA. The new DNA is not stainable with 33258 Hoechst, which is highly specific for thymidine. The temporal development of the fluorescence distributions after addition of BUdR to the growth medium has been investigated in the flow cytometer, and the data were used to calculate the mean durations of the phases G₁, S and G₂+ M in exponentially growing cultures as well as the cycle transit times in synchronized cultures. The percentage of non-cycling cells was determined in each experiment.     

Use of Bromodeoxyuridine For Cell Kinetic Studies In Intact Animals

Abstract. A method is described for the use of BUdR for tracing cell proliferation patterns in the intestinal mucosa of intact mice.
The method has several distinct advantages over existing methods.
Bromodeoxyuridine (BUdR) is a well-established alternative to tritiated thymidine ([³H]TdR) as a tracer for studying DNA replication. However, its use in cytological as opposed to biochemical studies has been largely confined to examination of metaphase spreads, particularly analysis of sister chromatid exchange (Block, 1982). For this, BUdR incorporation into DNA has been demonstrated using the fluorescent dye Hoechst 33258, together with fluorescence microscopy (Latt, 1973), or Giemsa staining (Perry & Wolf, 1974). Recently, introduction of a monoclonal antibody which recognizes BUdR in single-stranded DNA (Gratzner, 1982) has enabled BUdR to be used for studying cell cycle kinetics in a manner exactly analogous to the use of [³H]TdR. This has been reported for whole cells in suspension and in monolayer (Dolbeare et al. , 1983; Dean et al. , 1984; Raza et al. , 1984). BUdR included in tissue culture medium is taken up and incorporated into newly synthesized DNA via the same pyrimidine salvage pathway as [³H]TdR (thymidine kinase). A concentration of as little as 10 μm—well below cytotoxic levels (Cerni, 1984)—is sufficient to give readily detectable labelling by immunocytochemistry with a pulse of less than 15 min. the validity of BUdR labelling for cell kinetic studies has been well established in comparisons with other methods by Dolbeare et al. (1983), Dean et al. (1984), and Raza et al. (1984).
We describe here the use of BUdR together with an immunocytochemical detection system applied to sections of wax-embedded tissues, which provides a convenient method of cell cycle analysis in intact animals.     

Differential sensitivity to 5-bromodeoxyuridine during the S phase of synchronized myogenic cells

Synchronized myogenic cell cultures have been used to demonstrate differential sensitivity to BUdR during segments of the S period. Synchronization of the cells was achieved by two methods. First, cells were initiated in medium containing FUdR, an inhibitor of DNA synthesis. Following FUdR blockade reversal with TdR after 19 hr in vitro, the synchronized cells were allowed to replicate their DNA with BUdR for periods corresponding to early and late S. Determinations of percentage labeled cells during synchronization with FUdR indicate that about 90% of the cycling population of cells accumulates at the G1/S interface of the cell-cycle and that the duration of the S period following blockade reversal with TdR is not altered. Since BUdR is pulsed to these cultures immediately after the point of synchronization, a high degree of synchrony is obtained. In the second method of synchrony, cohorts of cells which had been in G2, late S, or early S during a BUdR pulse were collected in metaphase arrest with Colcemid and selectively removed from the cultures. With the mitotic selection method the point of synchronization occurred several hours after the BUdR pulse. In both methods the cells were allowed to resume myogenesis and scored for percentage fused nuclei after approx 50 hr in vitro. With both methods of synchrony, BUdR incorporation into early replicating DNA results in a striking decline in myoblast fusion, whereas incorporation into late replicating DNA is without effect. The results cannot be attributed to a disproportionate uptake of nucleotide during early S. Further fractionation of the 4-hr S phase into 1-hr periods indicates that the BUdR sensitive target is replicated during the second hr of DNA synthesis.     

Cell cycle kinetics by BrdU-Hoechst flow cytometry: an alternative to the differential metaphase labelling technique

Human lymphocyte cell cycle kinetics was studied in parallel in whole blood and in isolated lymphocyte cultures by differential metaphase labelling and by flow cytometry, employing the principle of quenching of Hoechst fluorescence by BrdU substituted DNA. The BrdU-Hoechst flow technique yields information on the kinetics of cell recruitment and cell cycle progression superior to the differential metaphase staining, since it provides data from interphase cells, including cycle compartment durations, non-cycling cell fractions and transition probabilities. The Smith and Martin model, modified to include a fraction of non-cycling cells, yields excellent correspondence to the experimental data. We show that lymphocytes isolated from Ficoll gradients respond to PHA stimulation with a 4-6 hr delay compared to whole blood cultures or to cultures with autologous serum supplementation. A detailed study of the effects of such culture supplements on lag phase duration, cell cycle compartment length, non-cycling cell fractions and transition probabilities illustrates the application and reproducibility of the flow assay. The potential of the method is further documented with two examples showing the dependence of lymphocyte proliferation on donor age and donor genotype.     

Measurement of efflux from G1-phase in a growth factor dependent cell line

In order to test a mathematical model of G1/S-phase transition, the proliferative response of the murine myeloid interleukin 3 (IL-3) dependent cell line NFS-78 to graded reduction of IL-3 levels was measured. Exponentially growing cells were exposed to bromodeoxyuridine (BUdR), which replaces thymidine (TdR) in the DNA double strands during DNA synthesis. After incubation periods ranging from 3 to 36 h the cells were fixed and stained with a fluorescence dye mixture of Hoechst 33258 and ethidium bromide (EB) and subsequently analyzed in a two-parametrical flow cytometer. The BUdR-quenched TdR-specific Hoechst 33258 fluorescence of each cell provides information on the cell cycle location at the start of incubation and on whether or not a cell has divided. The DNA-specific EB fluorescence provides information on the actual cell cycle location at the end of the incubation period. From the 2-dimensional fluorescence distributions the efflux from G1-phase was calculated. Upon IL-3 reduction the cells showed accumulation in the Gl-phase along with a reduction in the progression rate through the other phases of the cell cycle. By staining with the vital dye Hoechst 33342 as well as with propidium iodide (PI) it was further possible to show that cell death after IL-3 withdrawal occurred in all phases of the cell cycle.     

Cell Cycle Kinetics By Brdu-Hoechst Flow Cytometry: an Alternative to the Differential Metaphase Labelling Technique

Abstract. Human lymphocytes cell cycle kinetics was studied in parallel in whole blood and in isolated lymphocyte cultures by differential metaphase labelling and by flow cytometry, employing the principle of quenching of Hoechst fluorescence by BrdU substituted DNA. the BrdU-Hoechst flow technique yields information on the kinetics of cell recruitment and cell cycle progression superior to the differential metaphase staining, since it provides data from interphase cells, including cycle compartment durations, non-cycling cell fractions and transition probabilities. the Smith and Martin model, modified to include a fraction of non-cycling cells, yields excellent correspondence to the experimental data. We show that lymphocytes isolated from Ficoll gradients respond to PHA stimulation with a 4-6 hr delay compared to whole blood cultures or to cultures with autologous serum supplementation. A detailed study of the effects of such culture supplements on lag phase duration, cell cycle compartment length, non-cycling cell fractions and transition probabilities illustrates the application and reproducibility of the flow assay. the potential of the method is further documented with two examples showing the dependence of lymphocyte proliferation on donor age and donor genotype.     

Bromodeoxyuridine-Induced Mutations in Synchronous Chinese Hamster Cells: Temporal Induction of 6-Thioguanine and Ouabain Resistance during DNA Replication

Mutations were induced in synchronous Chinese hamster cells by bromodeoxyuridine (BUdR) incorporated into cells for one-hour periods in the cell cycle. There was a very pronounced temporal dependence during the first half of the DNA synthesis period for the induction of damage leading to 6-thioguanine (6TG) and ouabain resistance. No mutants above background were induced by exposure to BUdR in G1 and G2 cells, and very few mutants were induced in the latter part of the DNA synthesis period. The peak for the induction of 6TG resistance occurs at about two hr in the DNA synthesis period; one hour later there is a peak for the induction of ouabain resistance. Both peaks occur before the time of maximum incorporation of BUdR into DNA. These results suggest that the mutagenesis by BUdR is associated with at least two nuclear genes, which replicate at two hr and three hr in the DNA synthesis period.     

Application of a DNA double labelling method for the flow cytometric analysis of recruitment of non-cycling cells in a mixed population of P and Q cells

Abstract. In this paper we describe the application of a non-radioactive DNA double labelling and staining method to an analysis of cell proliferation kinetics by flow cytometry, aimed at the direct measurement of recruitment rates in cell cultures. The method is based on the application of two halogenated deoxyuridines: iododeoxyuri-dine (IdUrd) and chlorodeoxyuridine (CldUrd) which are incorporated into DNA synthesizing cells. By applying two commercially available monoclonal antibodies both deoxyuridines can be detected separately. To measure recruitment all proliferating cells in a plateau phase culture were labelled first with IdUrd applied during a time interval approximately equal to the cell cycle time. Subsequently, recruitment induced by a medium change was analysed by flow cytometric assessment of incorporation of CldUrd in cells which had not taken up IdUrd.
Experiments designed to determine the toxicity of continuous labelling with IdUrd in different concentrations and of pulse labelling with CldUrd showed that there was no effect on the progression of cells through the cell cycle. The aim of this study is to test the sensitivity of the procedure to detect changes in proliferation kinetics, in particular the entrance of resting cells into the S phase. Although the cell culture model used is very simple, the results demonstrate clearly that a low rate of recruitment can be detected. It is suggested that the procedure described here is specific and sensitive enough to quantify changes in cell proliferation in tumours induced by various treatments and has advantages over other methods, which measure recruitment indirectly, or directly by using two radioactive thymidines.     

Methods for determining the proliferation kinetics of cells by means of 5-bromodeoxyuridine.

After treatment of cells with 5-bromodeoxyuridine (BUdR), the percentage of completely BUdR-labelled interphase nuclei is greater the longer the BUdR treatment. The labelling effect is visible after staining with the fluorochrome 33258 Hoechst and with Giemsa. Various formulae and a nomogram are presented by means of which the percentage of cells in S period, duration of the S period and the whole cell cycle can be determined by examination of a single preparation or by comparison of several preparations. The methods are tested using cell cultures of Microtus agrestis and compared with autoradiographic methods after labeling with 3H-thymidine.     

Sensitivity of flow cytometric data to variations in cell cycle parameters

Abstract We investigated to what extent flow cytometric DNA histograms are informative of cell cycle parameters. We created a computer program to simulate cell cycle progression in a generic and flexible way. Various scenarios, characterized by different models and distributions of cell cycle phase transit times, have been analysed in order to obtain the percentages of cells in the different cell cycle phases during exponential growth and their time course after mitotic block.
Cell percentages during exponential growth were insensitive to intercell variability in phase transit times and thus can be employed to estimate the relative mean phase transit times, even in the presence of non-cycling cells. However, this information is ambiguous if re-entry of such cells into the cycling status is permitted. The stathmokinetic outline gives the mean phase transit times, but also provides information about the spread, but not the form, of the phase transit time distributions, being particularly sensitive to the spread of G1 phase duration. The stathmokinetic outline also helps distinguish between scenarios considering only cycling cells, those forecasting a fraction of definitively non-cycling cells and those admitting a Go status with first-order output kinetics.     

Sensitivity of flow cytometric data to variations in cell cycle parameters

We investigated to what extent flow cytometric DNA histograms are informative of cell cycle parameters. We created a computer program to simulate cell cycle progression in a generic and flexible way. Various scenarios, characterized by different models and distributions of cell cycle phase transit times, have been analysed in order to obtain the percentages of cells in the different cell cycle phases during exponential growth and their time course after mitotic block. Cell percentages during exponential growth were insensitive to intercell variability in phase transit times and thus can be employed to estimate the relative mean phase transit times, even in the presence of non-cycling cells. However, this information is ambiguous if re-entry of such cells into the cycling status is permitted. The stathmokinetic outline gives the mean phase transit times, but also provides information about the spread, but not the form, of the phase transit time distributions, being particularly sensitive to the spread of G1 phase duration. The stathmokinetic outline also helps distinguish between scenarios considering only cycling cells, those forecasting a fraction of definitively non-cycling cells and those admitting a G0 status with first-order output kinetics.     

Cell Kinetic Evidence Suggests Elevated Oxidative Stress in Cultured Cells of Bloom's Syndrome

Bromodeoxyuridine/Hoechst flow cytometry was used to analyse disturbed cell proliferation of fibroblasts and lymphoblastoid cells from Bloom's syndrome (BS). Fibroblasts show poor activation, arrest in the G2 phase of the cell cycle along with a prolongation of the Gl phase. This pattern of perturbed cells proliferation is akin to that elicited in normal fibroblasts by 4-hydroxy-nonenal, a breakdown product of lipid peroxides. Treatment with vitamin E improved growth of BS fibroblasts more strongly than growth of normal fibroblasts. Lymphoblastoid cells from BS, to the contrary, experience only a minor arrest in the G2 phase after one round of bromodeoxyuridine incorporation, but are strongly inhibited during and after the second S phase. Thus, their cell cycle arrest is dependent upon BrdU incorporation, as has been found previously in normal cells exposed to elevated concentrations of oxygen or paraquat, a superoxide generating compound. These results suggest that BS cells may suffer from an elevated, endogenous generation of oxygen free radicals.     

METHODS FOR DETERMINING THE PROLIFERATION KINETICS OF CELLS BY MEANS OF 5-BROMODEOXYURIDINE

After treatment of cells with 5-bromodeoxyuridine (BUdR), the percentage of completely BUdR-labelled interphase nuclei is greater the longer the BUdR treatment. The labelling effect is visible after staining with the fluorochrome 33258 Hoechst and with Giemsa. Various formulae and a nomogram are presented by means of which the percentage of cells in S period, duration of the S period and the whole cell cycle can be determined by examination of a single preparation or by comparison of several preparations. The methods are tested using cell cultures of Microtus agrestis and compared with autoradiographic methods after labelling with ³H-thymidine.     

High resolution analysis of cell cycle-correlated vimentin expression in asynchronously grown,TPA-treated MPC-11 cells by the novel flow cytometric multiparameter BrdU-hoechst/PI and immunolabeling technique

High resolution, multiparameter analysis using the flow cytometric BrdU/Hoechst quenching technique has been applied to study cell cycle kinetics and vimentin expression in individual cells of asynchronously grown MPC-11 mouse plasmacytoma cell cultures treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) to induce in vitro differentiation. BrdU treatment up to 16 h in the absence or presence of TPA did not affect either cell cycle progression or the kinetics or quantity of vimentin expression. TPA-treated cells became arrested in G1 phase of the second cell cycle; however, this G1 phase arrest was transient only. In addition, G1 phase cells located prior to a putative transition point at the beginning of TPA treatment were completely blocked in cell cycle progression. There is also evidence that cells located in G1 or G2/M phase at the beginning of TPA treatment finally expressed low levels of vimentin. On the contrary, cells located in S phase at TPA exposure showed high vimentin levels after treatment. The results presented here show that, with the flow cytometric BrdU/Hoechst quenching technique, one can correlate time-dependent protein expression at the single cell level in asynchronously grown cultures not only with the actual cell cycle state, but also with the history of cell replication. © 1994 Wiley-Liss, Inc.     

De novo synthesis of glutathione is required for both entry into and progression through the cell cycle

To study the putative role of de novo synthesis of glutathione (GSH) in the regulation of the cell cycle, we exposed NIH-3T3 cells to buthionine sulfoximine (BSO) and analysed cell cycle kinetics with continuous bromodeoxyuridine (BrdU) labeling and bivariate Hoechst 33258/ethidium bromide flow cytometry. Treating quiescent cells, which themselves had a low GSH content, with BSO did not affect subsequent entry into and progression through the cell cycle. Adding BSO during serum stimulation, however, provoked a dose-dependent inhibition of cell growth and a delayed increase in GSH level. The cell kinetic mechanism underlying BSO-induced growth inhibition is a diminished entry into the cell cycle and a permanent arrest in the S and G2 phase of the cell cycle. Our results are consistent with the hypothesis that GSH de novo synthesis is required for cell activation and proper S and G2 phase transit. © 1995 Wiley-Liss, Inc.     

Regulation of the rate of cell cycle progression in quiescent cytolytic T cells by T cell growth factor: analysis by flow microfluorometry

We have previously shown that greater than 90% of B6.1 cells, a murine cytolytic T lymphocyte (CTL) cloned line which is solely dependent on T cell growth factor (TCGF) for continuous growth in vitro, accumulates in the G1 phase of the cell cycle after transfer into culture medium containing no TCGF. Moreover, when such quiescent cells are exposed again to TCGF, greater than 85% reenter the S phase and subsequently divide in a relatively synchronous fashion. In this study, the regulation of the rate of cell cycle progression of quiescent B6.1 cells after exposure to TCGF was analyzed using two complementary DNA staining techniques, namely, the propodium iodide method (to enumerate cells entering the S phase) and the Hoechst 33342-bromodeoxyuridine substitution technique (to enumerate cells which have gone through mitosis). After TCGF addition, quiescent B6.1 cells resumed DNA synthesis and divided after a lag phase of 10 and 20 h, respectively. The duration of the lag phase was found to be dependent on the length of time during which quiescent B6.1 cells had been deprived of TCGF, but was independent of the concentration of TCGF used for restimulation. In contrast, the proportion of cells responding to TCGF as well as the rate of their first passage through mitosis was dependent on TCGF concentration. The presence of TCGF for at least 6 h was required for a maximal response. Moreover, direct evidence was obtained that TCGF by itself was able to stimulate proliferation of quiescent B6.1 cells in the absence of other growth factors and serum constituents other than bovine serum albumin, transferrin, and lipids.