Tracer dose and availability time of thymidine and bromodeoxyuridine: application of bromodeoxyuridine in cell kinetic studies

Abstract. The present experiments with [¹⁴C]-thymidine (TdR) and [³H]-bromo-deoxyuridine (BrdU) using mouse jejunal crypt cells show that the upper limit of the tracer dose of TdR is about 0.5 µg g body weight^-1 and that of BrdU is about 5·0 µg g body weight^-1. Applying these doses, the proportions of the endogenous DNA synthesis attributed to the exogenous DNA precursor are 2% and 9% respectively. For [³H]-TdR doses commonly used in cell kinetic studies this proportion is only 0-1-1.0%, a negligible quantity that does not influence the endogenous DNA synthesis. The maximum availability time of tracer doses of TdR as well as BrdU is 40 to 60 min, the majority of the precursors being incorporated after 20 min. The availability time is the same for TdR doses exceeding the tracer dose by a factor of 80, whereas it is prolonged in the case of BrdU doses exceeding the tracer dose by a factor of 50. BrdU is suitable to replace radioactively labelled TdR in short term cell kinetic studies, i.e. determination of the labelling index or of the S phase duration by double labelling. However, more studies are needed to elucidate how far BrdU can replace TdR in long term studies as shown by differences between the fraction of labelled mitoses (FLM) curves of a human renal cell carcinoma measured with BrdU and [³H]-TdR.     

Double labelling of tissue combining tritiated thymidine autoradiography with immunodetection of bromodeoxyuridine: the autoradiographic significance of inhibition of thymidine incorporation into DNA by bromodeoxyuridine given simultaneously

We describe a reproducible method for combining tritiated thymidine ([H]TdR) autoradiography with immunoperoxidase detection of bromodeoxyuridine (BrdU) in paraffin-embedded tissues. The technique has been used to examine, in mouse tongue epithelium, the inhibition of incorporation into DNA of [3H]TdR by a simultaneous injection of BrdU in the doses that both compounds are likely to be used in cell proliferation studies. The significance that this inhibition has on prolongation of autoradiograph exposure times, to ensure that all cells that incorporate [3H]TdR are scored as positive, in particular the most lightly labelled cells, has been quantified. The inhibition of uptake into DNA of [3H]TdR from 0.23 to 1.85 MBq (6.25 to 50 mu Ci) per animal, produced by a simultaneous injection of 2.5 mg BrdU shows a linear, dose-dependent relationship. Provided the injected dose (in mu Ci per animal) multiplied by the autoradiographic exposure time (in days) is greater than a value of 700, then all cells that are labelled after incorporation of [3H]TdR alone are also labelled after simultaneous double labelling, despite the latter producing a lower average grain count.     

Double labelling of tissue combining tritiated thymidine autoradiography with immunodetection of bromodeoxyuridine: the autoradiographic significance of inhibition of thymidine incorporation into DNA by bromodeoxyuridine given simultaneously

Abstract We describe a reproducible method for combining tritiated thymidine ([³H]TdR) autoradiography with immunoperoxidase detection of bromodeoxyuridine (BrdU) in paraffin-embedded tissues. The technique has been used to examine, in mouse tongue epithelium, the inhibition of incorporation into DNA of [³H]TdR by a simultaneous injection of BrdU in the doses that both compounds are likely to be used in cell proliferation studies. The significance that this inhibition has on prolongation of autoradiograph exposure times, to ensure that all cells that incorporate [³H]TdR are scored as positive, in particular the most lightly labelled cells, has been quantified.
The inhibition of uptake into DNA of [³H]TdR from 0.23 to 1.85 MBq (6.25 to 50 μCi) per animal, produced by a simultaneous injection of 2.5 mg BrdU shows a linear, dose-dependent relationship. Provided the injected dose (in μCi per animal) multiplied by the autoradiographic exposure time (in days) is greater than a value of 700, then all cells that are labelled after incorporation of [³H]TdR alone are also labelled after simultaneous double labelling, despite the latter producing a lower average grain count.     

DNA-synthesizing cells in oral epithelium have a range of cell cycle durations: evidence from double-labelling studies using tritiated thymidine and bromodeoxyuridine

Mouse tongue epithelium is characterized by a circadian variation in the number of DNA-synthesizing cells (labelling index, LI). Cells undergoing DNA synthesis were labelled with tritiated thymidine [( 3H]TdR) at 0300 (peak LI) or 1200 h (low LI). The fate of these cells was assessed by injecting animals with bromodeoxyuridine (BrdU) at intervals from 12-48 h after [3H]TdR, to follow them from one cell cycle to the next. Labelling was revealed by combining [3H]TdR autoradiography with immunoperoxidase detection of BrdU in the same sections. A single peak in the appearance of double-labelled cells was seen at 44 h, if [3H]TdR was given at 1200 h; following [3H]TdR at 0300 h, a peak of double labelling was seen at 48 h with the possibility of smaller peaks at 24 h and 36 h. These results show that the 24 h periodicity in LI in this tissue is associated with a predominant cell cycle duration of 44-48 h, but that a few cells cycle more quickly. Double labelling with [3H]TdR and BrdU provides a useful method for establishing cell cycle duration by labelling S-phase cells in successive cell cycles.     

DNA-synthesizing cells in oral epithelium have a range of cell cycle durations: evidence from double-labelling studies using tritiated thymidine and bromodeoxyuridine

Abstract Mouse tongue epithelium is characterized by a circadian variation in the number of DNA-synthesizing cells (labelling index, LI). Cells undergoing DNA synthesis were labelled with tritiated thymidine ([³H]TdR) at 0300 (peak LI) or 1200 h (low LI). The fate of these cells was assessed by injecting animals with bromodeoxyuridine (BrdU) at intervals from 12–48 h after [³H]TdR, to follow them from one cell cycle to the next. Labelling was revealed by combining [³H]TdR autoradiography with immunoperoxidase detection of BrdU in the same sections.
A single peak in the appearance of double-labelled cells was seen at 44 h, if [³H]TdR was given at 1200 h; following [3H]TdR at 0300 h, a peak of double labelling was seen at 48 h with the possibility of smaller peaks at 24 h and 36 h.
These results show that the 24 h periodicity in LI in this tissue is associated with a predominant cell cycle duration of 44–48 h, but that a few cells cycle more quickly. Double labelling with [³H]TdR and BrdU provides a useful method for establishing cell cycle duration by labelling S-phase cells in successive cell cycles.     

Mathematical model analysis of mouse epidermal cell kinetics measured by bivariate DNA/anti-bromodeoxyuridine flow cytometry and continuous [3H]-thymidine labelling

In a previous study the epidermal cell kinetics of hairless mice were investigated with bivariate DNA/anti-bromodeoxyuridine (BrdU) flow cytometry of isolated basal cells after BrdU pulse labelling. The results confirmed our previous observations of two kinetically distinct sub-populations in the G2 phase. However, the results also showed that almost all BrdU-positive cells had left S phase 6-12 h after pulse labelling, contradicting our previous assumption of a distinct, slowly cycling, major sub-population in S phase. The latter study was based on an experiment combining continuous tritiated thymidine [( 3H]TdR) labelling and cell sorting. The purpose of the present study was to use a mathematical model to analyse epidermal cell kinetics by simulating bivariate DNA/BrdU data in order to get more details about the kinetic organization and cell cycle parameter values. We also wanted to re-evaluate our assumption of slowly cycling cells in S phase. The mathematical model shows a good fit to the experimental BrdU data initiated either at 08.00 hours or 20.00 hours. Simultaneously, it was also possible to obtain a good fit to our previous continuous labelling data without including a sub-population of slowly cycling cells in S phase. This was achieved by improving the way in which the continuous [3H]TdR labelling was simulated. The presence of two distinct subpopulations in G2 phase was confirmed and a similar kinetic organization with rapidly and slowly cycling cells in G1 phase is suggested. The sizes of the slowly cycling fractions in G1 and G2 showed the same distinct circadian dependency. The model analysis indicates that a small fraction of BrdU labelled cells (3-5%) was arrested in G2 phase due to BrdU toxicity. This is insignificant compared with the total number of labelled cells and has a negligible effect on the average cell cycle data. However, it comprises 1/3 to 1/2 of the BrdU positive G2 cells after the pulse labelled cells have been distributed among the cell cycle compartments.     

Cell proliferation kinetics of six xenografted human cervix carcinomas: comparison of autoradiography and bromodeoxyuridine labelling methods

Cell kinetic and histologic parameters of six xenografted tumours with volume doubling times ranging from 6 to 43 d were investigated in order to obtain kinetic information on a panel of tumours to be used in radiobiological studies. The six tumours covered a range of histologies and their DNA indices varied from 2.7 to 1.4. The length of the cell cycle (Tc), potential doubling time (Tpot) and labelling index (LI) were determined by continuous labelling with [3H]TdR and autoradiography in three tumours, Tc varied from 30 to 40 h. Determinations of the length of the S phase (Ts) were found to be less reliable by this method. Data on Ts and LI were also determined in all six tumours using bromodeoxyuridine (Brd) labelling and the single sample method: values of Tpot were slightly longer than those obtained via the autoradiographic method. In addition, multiple samples were taken after BrdU labelling. Tc was determined by fitting the data obtained from mid-S, mid-G2 and mid-G1 windows to curves described by a damped oscillator. Data obtained via the mid-S window were found to be most reliable. Generally, cell cycle times obtained by the BrdU method were longer than those observed with the autoradiographic method. Differences between the two methods could be explained by inaccuracies in the determination of Ts, LI and Tc and differences in the experimental approach. We consider the BrdU labelling method to be a suitable alternative for the time-consuming autoradiography, if data on Ts or Tpot are sufficient. Due to difficulties in the reproducibility of the immunofluorescence staining and asynchronization of cells approximately 10 h after labelling, the method of windows analysis was affected by similar problems to those observed in interpretation of percentage labelled mitosis (PLM) curves. However, the method may serve as an alternative to determine cell cycle times in vitro and, if improved technically, in vivo. Careful comparison of the data obtained from mid-S, mid-G1 and mid-G2 windows may increase the reliability of the determination of cell kinetic parameters.     

Mathematical model analysis of mouse epidermal cell kinetics measured by bivariate DNA/anti-bromodeoxyuridine flow cytometry and continuous [3H]-thymidine labelling

Abstract. In a previous study the epidermal cell kinetics of hairless mice were investigated with bivariate DNA/anti-bromodeoxyuridine (BrdU) flow cytometry of isolated basal cells after BrdU pulse labelling. The results confirmed our previous observations of two kinetically distinct sub-populations in the G₂ phase. However, the results also showed that almost all BrdU-positive cells had left S phase 6–12 h after pulse labelling, contradicting our previous assumption of a distinct, slowly cycling, major sub-population in S phase. The latter study was based on an experiment combining continuous tritiated thymidine ([³H]TdR) labelling and cell sorting. The purpose of the present study was to use a mathematical model to analyse epidermal cell kinetics by simulating bivariate DNA/BrdU data in order to get more details about the kinetic organization and cell cycle parameter values. We also wanted to re-evaluate our assumption of slowly cycling cells in S phase. The mathematical model shows a good fit to the experimental BrdU data initiated either at 08.00 hours or 20.00 hours. Simultaneously, it was also possible to obtain a good fit to our previous continuous labelling data without including a sub-population of slowly cycling cells in S phase. This was achieved by improving the way in which the continuous [³H]TdR labelling was simulated. The presence of two distinct sub-populations in G₂ phase was confirmed and a similar kinetic organization with rapidly and slowly cycling cells in G₁ phase is suggested. The sizes of the slowly cycling fractions in G₁ and G₂ showed the same distinct circadian dependency. The model analysis indicates that a small fraction of BrdU labelled cells (3–5%) was arrested in G₂ phase due to BrdU toxicity. This is insignificant compared with the total number of labelled cells and has a negligible effect on the average cell cycle data. However, it comprises 1/3 to 1/2 of the BrdU positive G₂ cells after the pulse labelled cells have been distributed among the cell cycle compartments.     

Combined flow and absorption DNA measurements of [3H]TdR-labelled tumour cells. I. Studies of MCa-11 cells grown as tumours in vivo and as exponential cultures in vitro

Flow cytometry of cellular DNA content provides rapid estimates of DNA distributions, i.e. the proportions of cells in the different phases of the cell cycle. Measurements of DNA alone, however, yield no kinetic information and can make it difficult to resolve the cell cycle distributions of normal and transformed cells present in tumour biopsy specimens. The use of absorption cytophotometry of the Feulgen DNA content and [3H]TdR labelling of the same nuclei provides objective criteria to distinguish the ranges of DNA content for G0/G1, S, and G2/M cells. We now report on a study in which we combined flow and absorption cytometry to resolve the cell cycle distributions of host and tumour cells present in biopsy specimens of MCa-11 mouse mammary tumours labelled in vivo for 0.5 hr with [3H]TdR. A similar analysis of exponential monolayer cultures, labelled for 5 min with [3H]TdR under pulse-chase conditions, revealed a highly synchronous traversal of almost all cells through the different phases of the cell cycle. Combination of the flow and absorption methods also allowed us to detect G2 tumour cells in vivo and a minor tumour stem-line in vitro, to show that these two techniques are complementary and yield new information when they are combined.     

Effects of pulse labelling with tritiated thymidine on the circadian rhythmicity in epidermal cell-cycle distribution in mice

The influence of pulse labelling with 50 microCi tritiated thymidine ( [3H]TdR) (2 microCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G2 phases of the cell cycle were estimated from the obtained DNA frequency distributions. The proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [3H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [3H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G2 and M phase during the first 32 hr after the injection. The number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 microCi [3H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

Double labelling with bromodeoxyuridine and [3H]-thymidine of proliferative cells in small intestinal epithelium in steady state and after irradiation

The simultaneous immunohistochemical detection of bromodeoxyuridine (BrdU) and [3H]-thymidine ([3H]TdR), by conventional autoradiography, was performed on the mouse small intestine (ileum). Proliferation was studied under normal conditions as well as after 3 Gy of gamma-rays. The BrdU method in conjunction with [3H]TdR autoradiography appears to be reliable and useful for the study of cell kinetics especially in disturbed states, on condition that [3H]TdR is delivered to the animals before BrdU. It has been found that cells in the crypt are delayed by irradiation in their progression through the cell cycle predominantly in late S phase. The cells at the bottom of the crypt are more affected than the more differentiated but proliferating cells in the upper part of the crypt.     

Ultraviolet B irradiation induces epidermal regeneration with rapidly cycling cells

The left flank of hairless mouse skin was irradiated with a minimal erythema dose of ultraviolet B (UVB) light at 297 nm (25 mJcm-2), while the right flank served as untreated control. The alterations in epidermal growth kinetics induced by this UVB dose were studied with the percentage of labelled mitoses (PLM) technique during the period of increased proliferation. Thirty hours after irradiation, when a large cohort of cells appears in S phase, each animal was injected intra-peritoneally with 50 microCi tritiated thymidine [( 3H]-TdR). The number of labelled basal and suprabasal cells, as well as their localization in epidermis were registered in histological sections at short intervals up to 48 h after the [3H]-TdR pulse. Labelled mitoses were also counted in the same specimens. The results showed a four-fold increase of the high initial number of labelled cells in UVB-exposed epidermis within 18 h of the pulse injection, and a six-fold increase after 36 h. In control epidermis, where the starting value of the labelling index was much lower, there was only a three to four-fold increase in the number of labelled cells during the period studied. The PLM and the labelling index data were consistent with an average cell cycle time of approximately 10-12 h for UVB-exposed cells, in contrast to about 30 h for the fastest cycling population in control epidermis. The PLM curve also indicated a prolonged S phase duration in UVB-exposed epidermis compared with controls. In addition, labelled cells were seen in the suprabasal layer as early as 6 h after the [3H]-TdR injection and within 36 h labelled cells had reached the outermost layer of nucleated cells, indicating a reduced transit time through epidermis. The present study shows that a minimal erythema dose of UVB light at 297 nm induced a period of increased transit time through the S phase, combined with rapid cell proliferation, leading to an overall shortening of the epidermal cell cycle time. The cohort of cells labelled with [3H]-TdR 30 h after irradiation seemed to proceed as a wave of partially synchronized cells through the cell cycle for more than two rounds, which is comparable with the cell kinetic perturbations observed in regenerating mouse epidermis.     

Cell proliferation kinetics of six xenografted human cervix carcinomas: comparison of autoradiography and bromodeoxyuridine labelling methods

Abstract. Cell kinetic and histologic parameters of six xenografted tumours with volume doubling times ranging from 6 to 43 d were investigated in order to obtain kinetic information on a panel of tumours to be used in radiobiological studies. The six tumours covered a range of histologies and their DNA indices varied from 2–7 to 1–4. The length of the cell cycle (T_c), potential doubling time (T_pot) and labelling index (LI) were determined by continuous labelling with [³H]TdR and autoradiography in three tumours. T_c varied from 30 to 40 h. Determinations of the length of the S phase (T_s) were found to be less reliable by this method. Data on T_s and LI were also determined in all six tumours using bromodeoxyuridine (BrdU) labelling and the single sample method; values of T_pot were slightly longer than those obtained via the autoradiographic method. In addition, multiple samples were taken after BrdU labelling. T_c was determined by fitting the data obtained from mid-S, mid-G₂ and mid-G₁ windows to curves described by a damped oscillator. Data obtained via the mid-S window were found to be most reliable. Generally, cell cycle times obtained by the BrdU method were longer than those observed with the autoradiographic method. Differences between the two methods could be explained by inaccuracies in the determination of T_s, LI and T_c and differences in the experimental approach. We consider the BrdU labelling method to be a suitable alternative for the time-consuming autoradiography, if data on T_s or T_pot are sufficient. Due to difficulties in the reproducibility of the immunofluorescence staining and asynchronization of cells approximately 10 h after labelling, the method of windows analysis was affected by similar problems to those observed in interpretation of percentage labelled mitosis (PLM) curves. However, the method may serve as an alternative to determine cell cycle times in vitro and, if improved technically, in vivo. Careful comparison of the data obtained from mid-S, mid-G₁ and mid-G₂ windows may increase the reliability of the determination of cell kinetic parameters.     

Ultraviolet B irradiation induces epidermal regeneration with rapidly cycling cells

Abstract. The left flank of hairless mouse skin was irradiated with a minimal erythema dose of ultraviolet B (UVB) light at 297 nm (25 mJcm^-2), while the right flank served as untreated control. The alterations in epidermal growth kinetics induced by this UVB dose were studied with the percentage of labelled mitoses (PLM) technique during the period of increased proliferation. Thirty hours after irradiation, when a large cohort of cells appears in S phase, each animal was injected intra-peritoneally with 50 /iCi tritiated thymidine ([³H]-TdR). The number of labelled basal and suprabasal cells, as well as their localization in epidermis were registered in histological sections at short intervals up to 48 h after the [³H]-TdR pulse. Labelled mitoses were also counted in the same specimens. The results showed a four-fold increase of the high initial number of labelled cells in UVB-exposed epidermis within 18 h of the pulse injection, and a sixfold increase after 36 h. In control epidermis, where the starting value of the labelling index was much lower, there was only a three to four-fold increase in the number of labelled cells during the period studied. The PLM and the labelling index data were consistent with an average cell cycle time of approximately 10–12 h for UVB-exposed cells, in contrast to about 30 h for the fastest cycling population in control epidermis. The PLM curve also indicated a prolonged S phase duration in UVB-exposed epidermis compared with controls. In addition, labelled cells were seen in the suprabasal layer as early as 6 h after the [³H]-TdR injection and within 36 h labelled cells had reached the outermost layer of nucleated cells, indicating a reduced transit time through epidermis. The present study shows that a minimal erythema dose of UVB light at 297 nm induced a period of increased transit time through the S phase, combined with rapid cell proliferation, leading to an overall shortening of the epidermal cell cycle time. The cohort of cells labelled with [³H]-TdR 30 h after irradiation seemed to proceed as a wave of partially synchronized cells through the cell cycle for more than two rounds, which is comparable with the cell kinetic perturbations observed in regenerating mouse epidermis.     

Quantitative study of deoxycytidine incorporation in large and small lymphocytes of the mouse

Using radioautographic smear preparations of thymocytes and mesenteric lymph node (MLN) cells labelled with three different tritiated pyrimidine deoxyribonucleosides, the incorporation of DNA precursors was studied separately on large lymphocytes and small lymphocytes. Radioautographic reaction due to generally tritiated deoxycytidine ( [G-3H]CdR) labelling in vivo in large lymphocytes was more intense than that in small lymphocytes. When mice were sacrificed 6 hr after the administration of tritiated thymidine ( [3H]TdR), small lymphocytes were labelled more heavily than large lymphocytes. However, labelling intensity with [3H]TdR in large lymphocytes was greatly enhanced by the administration of 5-fluoro-deoxyuridine, whereas in small lymphocytes labelling intensity was only fairly enhanced by the same treatment. When cells were incubated in vitro with 5-tritium labelled deoxycytidine [( 5-3H]CdR) for 10 min, there was no significant difference in labelling intensities between large and small lymphocytes. In the case of [G-3H]CdR incorporation, the labelling intensity in large lymphocytes was found to be significantly stronger than that in small lymphocytes. Large as well as small lymphocytes incorporated [3H]TdR very well in vitro. However, addition of 5 X 0 X 10(-5) M of non-radioactive CdR to the medium greatly decreased the incorporation of [3H]TdR by large lymphocytes, whereas the effect of non-radioactive CdR in small lymphocytes was not so marked as that in large lymphocytes. Furthermore, the [3H]TdR-labelling percentages were decreased at the same rate by the addition of non-radioactive CdR in both large and small lymphocytes. These results indicate that large lymphocytes and a proportion of small lymphocytes have a strong tendency to convert CdR to thymidine mono-phosphate, which is utilized for DNA synthesis, whereas this ability is relatively weak in the rest of small lymphocytes. Thus, it is probably that this metabolic ability changes during the transition of the large lymphocyte to the small lymphocyte.     

Retention of labelled DNA precursor by murine cells after a single administration of tritium labelled thymidine

The central zone of the rat lens epithelium, extending half way from the centre to the periphery of a whole mount preparation, normally has less than 1% of the cells in the cell cycle at any given time. Mechanical wounding initiates a burst of proliferation in the central zone. DNA synthesis begins 14 hr after wounding followed by mitosis 10 hr later. When [3H]TdR was applied at 2 hr prior to S phase, some moderately heavy and some light labelling was observed after the onset of S phase. When [3H]TdR was applied 5 hr before S phase (9 hr after wounding), all the cells were lightly labelled. Only small amounts of the label were available to these cells 5 hr after application. It is significant that there was labelling in this group because it indicates the persistence of relatively small intracellular pools of [3H]TdR for several hours after the initial 'pulse' labelling of cells. Determinations of the duration of S phase were based on the assumption that pulse labelling may be affected by the persistence of the pools of [3H]TdR and consequent light labelling of the cells.     

Effects of Pulse Labelling With Tritiated Thymidine On the Circadian Rhythmicity In Epidermal Cell-Cycle Distribution In Mice

The influence of pulse labelling with 50 °Ci tritiated thymidine ([³H]TdR) (2 μCi/g) on epidermal cell-cycle distribution in mice was investigated. Animals were injected intraperitoneally with the radioactive tracer or with saline at 08.00 hours, and groups of animals were sacrificed at intervals during the following 32 hr. Epidermal basal cells were isolated from the back skin of the animals and prepared for DNA flow cytometry, and the proportions of cells in the S and G₂ phases of the cell cycle were estimated from the obtained DNA frequency distributions. the proportions of mitoses among basal cells were determined in histological sections from the same animals, as were the numbers of [³H]TdR-labelled cells per microscopic field by means of autoradiography. The results showed that the [³H]TdR activity did not affect the pattern of circadian rhythms in the proportions of cells in S, G₂ and M phase during the first 32 hr after the injection. the number of labelled cells per vision field was approximately doubled between 8 and 12 hr after tracer injection, indicating an unperturbed cell-cycle progression of the labelled cohort. In agreement with previous reports, an increase in the mitotic index was seen during the first 2 hr. These data are in agreement with the assumption that 50 °Ci [³H]TdR given as a pulse does not perturb cell-cycle progression in mouse epidermis in a way that invalidates percentage labelled mitosis (PLM) and double-labelling experiments.     

DIFFERENT LABELLING PATTERNS IN MOUSE LYMPHOID TISSUES WITH [3H]DEOXYCYTIDINE AND [3H]THYMIDINE

The percentages of labelled lymphocytes in smear preparations of mouse thymus were higher than those in similar preparations of mesenteric lymph nodes with either generally labelled tritiated deoxycytidine, [³H]CdR, or tritiated thymidine, [³H]TdR. Lymphocytes in the thymus cortex and in germinal centres of mesenteric lymph nodes were intensely labelled with [³H]CdR, whereas with [³H]TdR lymphocytes in the peripheral region of thymus and medullary cords of mesenteric lymph nodes were heavily labelled. The majority of lymphocytes in thymic cortex and germinal centres of mesenteric lymph nodes were labelled weakly with [³H]TdR. Thus, labelling patterns with [³H]CdR differed from those with [³H]TdR in lymphoid tissues of the mouse. Mouse lymphocytes can utilize [³H]CdR as a precursor molecule for cytosine and thymine in DNA. The ratio of radioactivity of thymine to that of cytosine was measured biochemically in DNA extracted from lymphocytes labelled with [³H]CdR. This radioactivity ratio in thymus was higher than that in mesenteric lymph nodes. These results suggest that the metabolic activities of utilizing CdR for DNA synthesis differ within lymphocyte populations in various lymphoid tissues in the mouse.     

Comparative analysis of different approaches to investigate cell kinetics

The potential of different methods to investigate proliferative activity of cell populations was analysed for non-Hodgkin's lymphomas. Cells in S phase and all cycling cells were determined on cell suspensions obtained from fresh lymph node material by [3H]-thymidine autoradiography [( 3H]TdR LI), a monoclonal antibody to bromodeoxyuridine (BrdU LI), and the monoclonal antibody Ki67. A good correlation was observed between the values of [3H]TdR LI and BrdU LI (rs = 0.90; P less than 0.01), [3H]TdR LI and S phase (rs = 0.62; P less than 0.01) and [3H]TdR LI and Ki67 (rs = 0.64; P less than 0.01) in individual lymphomas. Using the median values obtained from the different approaches as cut-off points to define slowly and rapidly proliferating tumours, the best agreement was observed between [3H]TdR LI and BrdU LI (91%) and poorer agreements, even though statistically significant, were observed between [3H]TdR LI and S phase (73%) or Ki67 (76%). In conclusion, the kinetic information derived from different approaches was more or less concordant and newly proposed approaches should be directly and carefully verified for their prognostic relevance before using them as alternatives to conventional methods.     

Combined flow and absorption DNA measurements of [3H]TdR-labelled tumour cells. I. Studies of MCa-11 cells grown as tumours in vivo and as exponential cultures in vitro*

Abstract. Flow cytometry of cellular DNA content provides rapid estimates of DNA distributions, i.e. the proportions of cells in the different phases of the cell cycle. Measurements of DNA alone, however, yield no kinetic information and can make it difficult to resolve the cell cycle distributions of normal and transformed cells present in tumour biopsy specimens. The use of absorption cytophotometry of the Feulgen DNA content and [³H]TdR labelling of the same nuclei provides objective criteria to distinguish the ranges of DNA content for G₀/G₁, S, and G₂/M cells. We now report on a study in which we combined flow and absorption cytometry to resolve the cell cycle distributions of host and tumour cells present in biopsy specimens of MCa-11 mouse mammary tumours labelled in vivo for 0.5 hr with [³H]TdR. A similar analysis of exponential monolayer cultures, labelled for 5 min with [³H]TdR under pulse-chase conditions, revealed a highly synchronous traversal of almost all cells through the different phases of the cell cycle. Combination of the flow and absorption methods also allowed us to detect G₂ tumour cells in vivo and a minor tumour stem-line in vitro, to show that these two techniques are complementary and yield new information when they are combined.