Flow cytometric estimation of cell cycle parameters using a monoclonal antibody to bromodeoxyuridine

An estimation of cell kinetic parameters was made by simultaneous flow cytometric measurements of DNA and bromodeoxyuridine (BrdUrd) contents of cells. The procedure described in this paper involves the incorporation of BrdUrd by S phase cells, labeling the BrdUrd with an indirect immunofluorescent technique using a monoclonal anti-BrdUrd antibody, and staining DNA with propidium iodide (PI). The amount of incorporated BrdUrd in HeLa cells was proportional to that of synthesized DNA through S phase. For all cell lines examined, the pattern of BrdUrd incorporation was essentially the same and the rate of DNA synthesis during S phase was not constant. The bivariate BrdUrd/DNA distributions showed a horse-shoe pattern, maximum in the mid S phase and minimum in the early and late S phases. Furthermore, the durations of cell cycle (Tc) and S phase (Ts) were estimated from a FLSm (fraction of labeled cells in mid S phase) curve that was generated by plotting the percentage of BrdUrd pulse-labeled cells in a narrow window defined in the mid S phase of the DNA histogram. The values of these parameters in NIH 3T3, HeLa S3, and HL-60 cells were in good accordance with the reported data. This FCM method using the monoclonal anti-BrdUrd antibody allows rapid determination of both cell cycle compartments and also Ts and Tc without the use of radioactive DNA precursors.     

Bromodeoxyuridine/DNA analysis of replication in CHO cells after exposure to UV light

The effects of ultraviolet light on cellular DNA replication were evaluated in an asynchronous Chinese hamster ovary cell population. BrdUrd incorporation was measured asa function of cell-cycle position, using an antibody against bromodeoxyuridine (BrdUrd) and dual parameter flow cytometric analysis. After exposure to UV light, there was an immediate reduction ( 50%) of BrdUrd incorporation in S phase cells, with most of the cells of the population being affected to a similar degree. At 5 h after UV, a population of cells with increased BrdUrd appeared as cells that were in G1 phase at the time of irradiation entered S phase with apparently increased rates of DNA synthesis. For 8 h after UV exposure, incorporation of BrdUrd by the original S phase cells remained constant, whereas a significant portion of original G1 cells possessed rates of BrdUrd incorporation surpassing even those of control cells. Maturation rates of DNA synthesized immediately before or after exposure by alkaline elution, were similar. Therefore, DNA synthesis measured in the short pulse by anti-BrdUrd fluorescence after exposure to UV light was representative of genomic replication. Anti-BrdUrd measurements after DNA damage provide quantitative and qualitative information of cellular rates of DNA synthesis especially in instances where perturbation of cell-cycle progression is a dominant feature of the damage. In this study, striking differences of subsequent DNA synthesis rates between cells in G1 or S phase at the time of exposure were revealed.     

Cell kinetics in mouse epidermis studied by bivariate DNA/bromodeoxyuridine and DNA/keratin flow cytometry.

Hairless mice were injected intraperitoneally with bromodeoxyuridine (Brd-Urd). Basal cells were isolated from epidermis, fixed in 70% ethanol, and prepared for bivariate BrdUrd/DNA flow cytometric (FCM) analysis. Optimum detection of incorporated BrdUrd in DNA was obtained by combining pepsin digestion and acid denaturation. The cell loss was reduced to a minimum by using phosphate-buffered saline containing Ca2+ and Mg2+ to neutralize the acid. The percentage of cells in S phase and the average uptake of BrdUrd per labelled cell in eight consecutive windows throughout the S phase were measured after pulse labelling at intervals during a 24 h period. Furthermore, the cell cycle progression of a pulse-labelled cohort of cells was followed up to 96 h after BrdUrd injection. In general the results from both experiments were in good agreement with previous data from 3H-thymidine labelling studies. The percentage of cells in S phase was highest at night and lowest in the afternoon, whereas the average uptake of BrdUrd per labelled cell showed only minor circadian variations. There were no indications that BrdUrd significantly perturbed normal epidermal growth kinetics. A cell cycle time of about 36 h was observed for the labelled cohort. Indications of heterogeneity in traverse through G1 phase were found, and the existence of slowly cycling or temporarily resting cells in G2 phase was confirmed. There was, however, no evidence of a significant population of temporarily resting cells in the S phase. Bivariate DNA/keratin FCM analysis revealed a high purity of basal cells in the suspensions and indicated that the synthesis of the differentiation-keratin K10 was turned on only in G1 phase and after the last division.     

Abnormal DNA synthesis in polyamine deficient cells revealed by bromodeoxyuridine—flow cytometry technique

Abstract. Chinese hamster ovary cells were seeded in the absence or presence of the polyamine synthesis inhibitor 2-difluoromethylornithine (DFMO). At 14 days after seeding, the cells were labelled for 15–120 min with the thymidine analogue bromo-deoxyuridine (BrdUrd) and they were then fixed directly after the labelling period. In addition, cells were labelled for 30 min and they were then allowed to progress in BrdUrd-free medium during a defined post-labelling time before fixation. An indirect immunofluorescence technique, using the monoclonal BrdUrd antibody and the intercalating stochiometric DNA stain, propidium iodide, was applied to enable quantification of cellular BrdUrd and DNA contents, respectively, by flow cytometry (FCM). By comparing the mean DNA content of BrdUrd-labelled cells to the mean DNA contents of G₁ and G₂ cells, a relative measure of the position of the BrdUrd-labelled cells was obtained (relative movement). Relative movement data, obtained from control and DFMO-treated cells fixed directly after BrdUrd labelling, indicated that DFMO-treated cells entered S phase at a normal rate, while their progression through S phase was impaired. DNA histograms of BrdUrd-labelled control cells fixed directly after labelling showed that most cells were found in early and late S phase, while DNA histograms of BrdUrd-labelled DFMO-treated cells showed that most cells were in early S phase, indicating a delayed progression through S phase. Analysis of relative movement of cells that were allowed to progress in BrdUrd-free medium after labelling showed that DFMO treatment resulted in a significant lengthening of the DNA synthesis time. Labelling index was significantly higher in DFMO-treated, growth-inhibited cells than in early plateau phase control cells indicating an S phase accumulation in the former cells.     

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.     

Flow cytometric analysis of the kinetic effects of cisplatin on lung cancer cells

The effects of cisplatin on the cell cycle and DNA synthesis of human lung adenocarcinoma cell line PC-9 were examined by flow cytometry. The cellular DNA content and the bromodeoxyuridine (BrdUrd) incorporation rate were measured simultaneously using a monoclonal anti-BrdUrd antibody. Following exposure to cisplatin (1.0 micrograms/ml) for 1 and 24 hr, the bivariate DNA/BrdUrd distributions revealed a delayed S-phase transit and an accumulation of cells in the G2M phase. The BrdUrd-linked green fluorescence intensity continued to decrease with the lapse of time. However, early- and mid-S-phase cells soon recovered DNA synthesis activity, and the former showed higher activity than the control cells. These findings suggested the vigorous DNA synthesis of cells in early S phase. However, for quantitative analysis of chemotherapeutic effects, some problems remained to be resolved regarding the condition for DNA denaturation and its alteration by the agents.     

In vitro bromodeoxyuridine-labelling of single cell suspensions: effects of time and temperature of sample storage

The present study was aimed to explore how the in vitro BrdUrd-labelling of rat thymocytes might be affected by both the time elapsed between obtaining the sample and the beginning of the labelling (0, 15, 30 or 60 min) and the effect of the temperature of storage (4°C versus room temperature). Single cell suspensions obtained after in vivo labelling with BrdUrd were used as controls. The S phase fraction was calculated by flow cytometry both according to BrdUrd-immunolabelling and DNA content. Immediate incubation with BrdUrd after the sample was obtained resulted in a slight decrease of the proportion of S phase cells analysed either according to DNA content or to BrdUrd-immunolabelling. Regardless of storage-temperature, the S phase fraction decreased in samples kept for 15 min or more before BrdUrd incubation. No BrdUrd-positive cells were detected in samples stored for 60 min at room temperature. This effect was related to temperature since positive cells were found when the samples were kept at 4°C during the same time period. Our results suggest that during in vitro incubation a relative loss of S phase cells exists and that a delay beyond 15 min between obtaining the sample and the in vitro labelling seriusly compromises the results of this technique.     

Flow cytometric measurement of cell cycle kinetics in rat Walker-256 carcinoma following in vivo and in vitro pulse labelling with bromodeoxyuridine.

Flow cytometric measurements of total DNA content, cell cycle distribution, and bromodeoxyuridine (BrdUrd) uptake were made in rat Walker-256 carcinoma cells. After both in vivo and in vitro pulse labelling with BrdUrd, Walker-256 tumor cells were stained with propidium iodide (PI) to estimate the total DNA content and a monoclonal antibody against BrdUrd to estimate the relative amount of cells in S phase. BrdUrd-labelled single cell suspensions were harvested at different time intervals to determine the movement of these cells within the cell cycle. To increase BrdUrd uptake, fluorodeoxyuridine (FDU), a thymidine antagonist, was also applied in vivo and in vitro. The results indicated exponential growth characteristics for this tumor between days 5 and 8 after implantation. Tumor doubling times, derived from changes in tumor volume in vivo and from the increase in cell number in vitro were similar. The mean time for DNA synthesis was estimated from the relative movement of BrdUrd-labelled cells towards G2. The percent of cells labelled with BrdUrd and the DNA synthesis time were similar regardless of the mode of BrdUrd administration. This study demonstrates that BrdUrd labelling of rat Walker-256 carcinoma cells in vitro yields kinetic estimates of tumor proliferation during exponential growth similar to those with the administration of BrdUrd in the intact tumor-bearing rat.     

Intratumoral heterogeneity of S phase transition in solid tumours determined by bromodeoxyuridine labelling and flow cytometry

Abstract. Cell kinetics of human renal cell carcinomas xenotransplanted into nu/nu mice were analysed using the bromodeoxyuridine (BrdUrd) labelling method. Tumours were removed 0.5–14 h after injection of the BrdUrd solution. The tumour cells were stained with fluorescein isothiocyanate conjugated anti-BrdUrd antibodies and propidium iodide (DNA content). From the flow cytometry data the relative movement was calculated. Relative movement data of variable intervals after BrdUrd labelling were subjected to a fit procedure using log-normal distributions for S phase transition (T_s). The log-normal distributions were modified by inflation factors in order to get extremely asymmetric distributions. The best fits to the experimental data were obtained using wide asymmetric T_s distributions, indicating that progression through S phase in solid human tumours is considerably heterogeneous. This implies that the potential doubling time (T_pot) is longer than calculated from a single measured relative movement value obtained a few hours after BrdUrd labelling.     

Gradient fractionation of cycling and resting cells monitored by BrdUrd incorporation

A number of techniques are currently employed for the fractionation of heterogeneous cell populations or for the separation of cells in different phases of their cycle. With the development of osmotically inert colloidal silica particles media, density gradient centrifugation became an established method for the separation and purification of cells and subcellular particles. We have applied this technique to the separation of cycling from resting Friend erythroleukemia cells, to obtain purified populations for further biological assays. The flow cytometric analysis of DNA content of the different fractions obtained by the gradient and stained with Propidium Iodide (PI), showed the S compartment highly concentrated in the 1.073/77 g/ml interface, while the upper levels of the gradient were highly enriched of cells in G1 phase. Moreover, the dual parameter analysis of DNA content by means of Bromodeoxyuridine (BrdUrd) incorporation and PI staining, showed that part of the cells in the 1.067/73 fraction represented the early S phase even if their DNA level, measured on the basis of PI fluorescence was within the diploid cell cluster. This method seems to be suitable to obtain pure cell fractions even when dealing with numerically large populations.     

Differentiation of mitotic melanoma cells from G2 cells and their isolation by use of 5-bromo-2'-deoxyuridine and propidium iodide

This report describes a method by which mitotic cells were isolated from nonsynchronized Cloudman melanoma cells that had been pulse labeled with 5-bromo-2'-deoxyuridine (BrdUrd) and double-stained with a fluoresceinated monoclonal antibody to BrdUrd and with propidium iodide (PI). In initial experiments, melanoma cells were first pulse labeled with BrdUrd, treated with prostaglandin E1 (PGE1 10 micrograms/m1) or vehicle (0.1% ethanol) for up to 24 hours, then stained with anti-BrdUrd and PI. PGE1-treated cells monitored at 3-hour intervals were observed to migrate from S phase to G2 phase, then, enigmatically, back into the late S phase region of the distribution. In other experiments, cells treated with PGE1 were pulse labeled with BrdUrd at the end of the treatment period and harvested. In these experiments, there was a small, discrete subpopulation of cells within the late S phase region of the DNA distribution that was negative for anti-BrdUrd. This subpopulation of cells was sorted and examined by light microscopy. We observed that 95% of these BrdUrd-negative "S phase" cells were mitotic cells. Since mitotic cells and G2 cells have equivalent amounts of DNA, the reduced red fluorescence exhibited by these cells may be due to a greater sensitivity to denaturation, which has been described for DNA of mitotic cells, and would account for the phenomenon of cells appearing to move "backwards" in the cell cycle. This report indicates that although the BrdUrd/PI method can further define the cell cycle into four compartments, it can also lead to over-estimation of S phase cells in kinetic studies because of contaminating mitotic cells.     

Retinoblastoma cell cycling

Techniques for the measurement of bromodeoxyuridine (BrdUrd) positive cells generally include either microscopic evaluation of paraffin embedded sections or measurements on cell suspensions using a fluorescent activated cell sorter. The accuracy of these measurements and their correlations can be affected by a number of technical and intrinsic tumor factors. Extrinsic parameters including degree of necrosis and tumor growth fraction are less easily analyzed in BrdUrd stained material. Retinoblastoma tumor cell cycling was prospectively studied in 11 children using in vivo and one child using in vitro BrdUrd. BrdUrd measurements were made by staining cell suspensions or sections of paraffin embedded tumor and analyzing by microscopy. Approximately 14% of viable cells were in the synthesis-phase of the cell cycle. The correlation between BrdUrd in cell suspensions and BrdUrd in paraffin embedded sections did not reach significance (r = 0.48). DNA analysis of these tumors was also performed using flow cytometry. Nine tumors were found to have a normal diploid DNA content, one had a G1 peak below the diploid control, two had a G1 peak above the diploid control, and one had two G1 peaks (a diploid and a hyperdiploid peak). There was no correlation between abnormal DNA content and the percent of cells in synthesis.     

Gradient fractionation of cycling and resting cells monitored by BrdUrd incorporation

Summary A number of techniques are currently employed for the fractionation of heterogeneous cell populations or for the separation of cells in different phases of their cycle. With the development of osmotically inert colloidal silica particles media, density gradient centrifugation became an established method for the separation and purification of cells and subcellular particles. We have applied this technique to the separation of cycling from resting Friend erythroleukemia cells, to obtain purified populations for further biological assays. The flow cytometric analysis of DNA content of the different fractions obtained by the gradient and stained with Propidium lodide (PI), showed the S compartment highly concentrated in the 1.073/77g/ml interface, while the upper levels of the gradient were highly enriched of cells in G₁ phase. Moreover, the dual parameter analysis of DNA content by means of Bromodeoxyuridine (BrdUrd) incorporation and PI staining, showed that part of the cells in the 1.067/73 fraction represented the early S phase even if their DNA level, measured on the basis of PI fluorescence was within the diploid cell cluster. This method seems to be suitable to obtain pure cell fractions even when dealing with numerically large populations.     

Cell-Cycle Analysis Using A Monoclonal Antibody to Brdurd

The flow cytometric measurement of DNA distributions of cells has many applications in biomedical research. Phase fractions estimated (calculated) from such distributions are used to study the growth characteristics of various types of cells, particularly when the cells have been exposed to perturbing agents such as chemotherapeutic drugs. For more than 10 years many methods for resolving DNA distributions into the three cell subpopulations (G₁, S and G₂, + M) have been reported in the literature. A new method of analysis utilizing a monoclonal antibody to bromodeoxyuridine (BrdUrd) has been developed (Gratzner, 1982; Dolbeare et al., 1983) which makes it possible in most cases to accurately determine phase fractions without resorting to mathematical models. the procedure involves the incorporation of BrdUrd by growing (DNA synthesizing) S phase cells, labelling the BrdUrd with a fluorescent monoclonal antibody, and the bivariate measurement of the antibody and of total DNA content, the latter through propidium-iodide staining. the resulting bivariate distributions clearly and simply resolve the three subpopulations. This paper describes the method and illustrates its use in the analysis of various fractions of elutriated exponentially growing Chinese hamster ovary (CHO) cells.     

Cell cycle perturbation by sodium butyrate in tumorigenic and non-tumorigenic human urothelial cell lines assessed by flow cytometric bromodeoxyuridine/DNA analysis

The effect of sodium butyrate on cell proliferation was studied in eight human urothelial cell lines differing in transformation grade (TGr): Hu 1752 (mortal, TGr I); HCV29 (immortal and tumorigenic, TGr II); HCV29T, T24, T24A, T24B, Hu 961A and Hu 1703He (tumorigenic, TGr III). In all cell lines, except Hu 1752, addition of 4 mm sodium butyrate at 18 h after replating resulted in a significantly decreased population of adherent cells after a further 24–48 h. This might partially be explained by detachment of cells, probably mainly S phase cells, from the substrate in the lines HCV 29, HCV29T, Hu 961A and Hu 1703He. Flow cytometric DNA analysis of the adherent cell population showed that all TGr II and III urothelial cell lines were DNA aneuploid, and that butyrate perturbed the cell cycle distribution in these cell lines, mainly by a decrease of the S phase fraction. Flow cytometric bromodeoxyuridine (BrdUrd)/DNA analysis of continuously BrdUrd labelled cultures, using a ‘washless’ BrdUrd/DNA staining technique, showed that butyrate inhibited the G_0/1-S phase transition, indicated by a delayed depletion of BrdUrd negative G_0/1 cells in the cell lines HCV29, HCV29T, T24B, Hu 961A and Hu 1703He. BrdUrd/DNA analysis further showed that butyrate inhibited the G₂M-G_0/1 phase transition, indicated by a pronounced accumulation of BrdUrd positive G₂M cells in the cell lines HCV29T, T24B, Hu 961A and Hu 1703He. Microscopy of HCV29T and Hu 961A cells indicated that this block did not occur in mitosis. The parental cell line T 24 and the cell line T 24 A did not show an accumulation of BrdUrd negative G_0/1 cells or BrdUrd positive G₂M cells like that occurring in the derived cell line T 24B.     

Rapid in vitro bromodeoxyuridine labeling method for monitoring of therapy response in solid human tumors

In vitro bromodeoxyuridine (BrdUrd) incubated single-cell suspensions obtained from solid tumors were fixed on slides for subsequent sample processing. As dispersal of nuclei largely was avoided, only small amounts of cells were needed for examination. The sensitivity of detecting even low BrdUrd incorporation rates could be improved by treatment with intense DNA denaturation conditions. This technique was applied to monitor cytokinetic response to chemotherapy and radiation in oral carcinomas by analysing biopsies taken consecutively in the course of treatment. By combining BrdUrd labeling and DNA flow cytometry, cells arrested in S phase easily could be distinguished from cells showing continuous proliferation.     

Bromodeoxyuridine labeling and flow cytometric identification of replicating Saccharomyces cerevisiae cells: lengths of cell cycle phases and population variability at specific cell cycle positions.

An immunofluorescent staining procedure has been developed to identify, with flow cytometry, replicating cells of Saccharomyces cerevisiae after incorporation of bromodeoxyuridine (BrdUrd) into the DNA. Incorporation of BrdUrd is made possible by using yeast strains with a cloned thymidine kinase gene from the herpes simplex virus. An exposure time of 4 min to BrdUrd results in detectable labeling of the DNA. The BrdUrd/DNA double staining procedure has been optimized and the flow cytometry measurements yield histograms comparable to data typically obtained for mammalian cells. On the basis of the accurate assessment of cell fractions in individual cell cycle phases of the asynchronously growing cell population, the average duration of the cell cycle phases has been evaluated. For a population doubling time of 100 min it was found that cells spend in average 41 min in the replicating phase and 24 min in the G2+M cell cycle period. Assuming that mother cells immediately reenter the S phase after cell division, daughter cells spend 65 min in the G1 cell cycle phase. Together with the single cell fluorescence parameters, the forward-angle light scattering intensity (FALS) has been determined as an indicator of cell size. Comparing different temporal positions within the cell cycle, the determined FALS distributions show the lowest variability at the beginning of the S phase. The developed procedure in combination with multiparameter flow cytometry should be useful for studying the kinetics and regulation of the budding yeast cell cycle.     

Estimating the variation in S phase duration from flow cytometric histograms

A stochastic model for interpreting BrdUrd DNA FCM-derived data is proposed. The model is based on branching processes and describes the progression of the DNA distribution of BrdUrd-labelled cells through the cell cycle. With the main focus on estimating the S phase duration and its variation, the DNA replication rate is modelled by a piecewise linear function, while assuming a gamma distribution for the S phase duration. Estimation of model parameters was carried out using maximum likelihood for data from two different cell lines. The results provided quite a good fit to the data, suggesting that stochastic models may be a valuable tool for analysing this kind of data.     

Enzymatic determination of nonrandom incorporation of 5-bromodeoxyuridine in rat DNA.

Secondary cultures of normal rat embryo cells were synchronized by a double thymidine block and pulsed with 10(-7) M 5-[3H]bromodeoxyuridine (BrdUrd) OR 10(-7) M[3H]thymidine during an entire S phase (7.5 h). To examine the pattern of [3H]thymidine, DNA was immediately extracted and purified at the completion of the S phase, CsCl density gradient centrifugation revealed that substitution for thymine by bromouracil was less than 7%. Single-strand specific nucleases obtained from Aspergillus oryzae and Neurospora crassa were allowed to react with native and partially depurinated (24-29%) [3H]BrdUrd-labeled rat DNA samples, and the products were assayed by hydroxylapatite column chromatography. Approximately 4-6% of the native, nondepurinated rat DNA was hydrolyzed by both nucleases. However, 24-28% of the partially depurinated, [3H] thymidine-labeled rat DNA was hydrolyzed by both enzymes as determined by loss of mass as well as radioactivity. Whereas comparable levels of depurinated, [3H]BrdUrd-labeled DNA were physically hydrolyzed by both nucleases, nearly 65% of the radioactivity was not recovered. Native, as well as depurinated, enzyme-treated DNA samples were sequentially and preparatively reassociated into highly repetitive, middle repetitive, and nonrepetitive nucleotide sequence components. The absolute and relative specific activities of each subfraction of native [3H]thymidine-labeled DNA were comparable. [3H]BrdUrd was differentially concentrated in the middle repetitive sequences as compared to other reiteration frequency types. When depurinated, nuclease-treated DNA samples were similarly fractionated, [3H]thymine moieties were uniformly distributed thoughout all sequences. However, a differential loss of [3H]BrdUrd moieties was detected predominantly from the middle repetitive nucleotide fraction. Melting profiles of the renatured DNA samples were characteristic of each respective DNA subfraction regardless of isotopic precursor. These results suggest that [3H]BrdUrd may be differentially incorporated into A + T rich clusters of rat DNA, especially in the moderately repeated chromosomal elements.