CELL LOSS FROM SEVERAL TYPES OF SOLID MURTNE TUMOUR: COMPARISON OF 125I-IODODEOXYURIDINE AND TRITIATED THYMIDINE METHODS

The method of measuring tumour cell loss rates in situ following radioactivity loss after a single injection of ¹²⁵I-iododeoxyurudine (¹²⁵I-UdR) was tested for its accuracy in five different types of murine tumour. To achieve this the method was compared with two others: (1) using ¹²⁵I-UdR, but excising tumours before the radioactivity determinations, with or without extracting DNA; (2) using tritiated thymidine and autoradiography. A third method was used on three of the tumours, in which ¹²⁵I-UdR-labelled tumours were grown in unlabelled hosts, followed by whole body counting of the tumour-bearing mice. In two of the tumours an increase was observed in total tumour radioactivity with time after ¹²⁵I-UdR injection. This prevented the estimation of cell loss parameters in these tumours. Approximately half the increase was due to reutilization of ¹²⁵I-UdR supplied from tissues within the mouse; approximately a third to an influx of labelled inflammatory cells (probably in response to infection accompanying ulceration of overlying skin); and the remainder to an increase in non-DNA radioactivity. In these tumours cell loss rates could be obtained from the whole body counting technique in which influxes of labelled cells and reutilizable radioactivity were eliminated. A comparison of either ¹²⁵I-UdR technique with the ³H-TdR technique showed good agreement of the cell loss factors for the low cell loss tumours. However, for tumours with high cell loss factors the ¹²⁵I-UdR technique gave lower values for cell loss. This implied that reutilization of ¹²⁵I-UdR within the tumour (i.e. from internal, not external sources) occurred in the high cell loss tumours. It is concluded that equating radioactivity loss with cell loss after an injection of ¹²⁵I-UdR is reasonable for some tumours, but will result in significant underestimates in others. For high cell loss tumours the ³H-TdR technique will give the     

Evaluation of radio- and chemotoxic effects of125I-UdR on tumour growth and host survival

Summary The toxicity of 5-iodo-2-deoxyuridine (I-UdR) was assayed in male C57 BL/6J mice bearing the syngeneic mammary adenocarcinoma EO 771 by injecting different doses of cold I-UdR or 125-iodine labelled I-UdR. Host survival, tumour growth, DNA-precursor incorporation, whole-body retention and tumour activity loss rates were chosen as biological end points.There was no measurable effect on host survival up to doses of 5 µg I-UdR or 50 µCi¹²⁵I-UdR per mouse during a mean life-span of 25 days. Adjusted to a constant amount of 0.55 µg I-UdR/mouse, radiotoxicity of¹²⁵I-UdR on tumour growth (up to 17 days after implantation), tracer incorporation, whole-body and tumour retention (up to 12 days after¹²⁵I-UdR injection) could be excluded up to a dosage of 50 µCi¹²⁵I-UdR/mouse.It is concluded that in situ evaluation of tumour activity loss rates in carcinoma EO 771 is not disturbed by toxic effects of I-UdR or¹²⁵I-UdR within the dose limits mentioned.     

Study of cell death in Friend leukaemia.

Cell death of splenic Friend leukaemic cells has been studied in vivo, using 125I-UdR and 3H-TdR pulse labelling. The evolution of the splenic specific activity has been measured by autoradiography and external counting during 40 hr after injection of the labelled precursor. These two techniques show the existence of a large reutilization of 3H-TdR (50%), which is measurable as soon as 7 hr after the injection. The DNA turnover rate is rapid, 83-8% of the splenic cellular DNA being renewed per day. Those results confirm that most of the cells produced in the Friend leukaemic spleen are rapidly lost; they also demonstrate that this cell loss is mainly due to a massive death, which occurs in proerythroblastic and erythroblastic compartments after one or two cell divisions. Friend leukaemic cells, which are characterized by a limited capacity of proliferation and a short lifespan, do not appear to be malignant.     

STUDY OF CELL DEATH IN FRIEND LEUKAEMIA

Cell death of splenic Friend leukaemic cells has been studied in vivo, using ¹²⁵I-UdR and ³H-TdR pulse labelling. The evolution of the splenic specific activity has been measured by autoradiography and external counting during 40 hr after injection of the labelled precursor. These two techniques show the existence of a large reutilization of ³H-TdR (50%), which is measurable as soon as 7 hr after the injection. The DNA turnover rate is rapid, 83-8 % of the splenic cellular DNA being renewed per day. These results confirm that most of the cells produced in the Friend leukaemic spleen are rapidly lost; they also demonstrate that this cell loss is mainly due to a massive death, which occurs in proerythroblastic and erythroblastic compartments after one or two cell divisions. Friend leukaemic cells, which are characterized by a limited capacity of proliferation and a short lifespan, do not appear to be malignant.     

The Effect of X-Irradiation On Cell Loss In Five Solid Murine Tumours, As Determined By the 125Iudr Method

The rate of cell loss in irradiated RIF-1, EMT6, KHJJ, B16 and KHT tumours was studied using the ¹²⁵IUdR loss technique. Administration of ¹²⁵IUdR preceded localized tumour irradiation by 2 days. Loss of tumour radioactivity was measured for 6–8 days after irradiation. the blood flow to some tumours was occluded during, and for 30 min following, injection of the label to measure the amount of radioactivity entering the tumour as a result of reutilization of label from the gut epithelia and influx of labelled host cells. Irradiation did not significantly alter the amount of radioactivity entering these clamped tumours during the 8–10 days after injection of ¹²⁵IUdR. This permitted comparison of irradiated and control groups based on the loss of radioactivity from the non-occluded tumours. Irradiation of RIF-1, EMT6, KHJJ or B16 tumours with doses of 600, 1400, 2400 or 4400 rads produced no significant increase in the rate of loss of tumour radioactivity. This suggested that, in the population of labelled cells, cell lysis following irradiation proceeded slowly. In contrast, KHT tumours showed a significant increase in loss rate following each radiation dose, although the increase was dose-independent. In all tumour systems, the constant rate of cell loss after radiation appeared to coincide with published reports of tumour growth responses after irradiation. the present data suggest that the manner of expression of radiation-induced cell killing results from the cellular proliferative status, i.e. whether a cell is cycling or non-cycling.     

CELL LOSS FROM THREE ESTABLISHED LINES OF THE C3H MOUSE MAMMARY TUMOR: A COMPARISON OF THE 125I-UdR AND THE 3H-TdR-AUTORADIOGRAPHIC METHODS

The¹²⁵I-UdR method for measuring cell loss from solid tumors has been re-evaluated. The rate of tumor cell loss from three established lines (S102F, S102S and Slow) of the C3H mouse mammary tumor was determined by the ¹²⁵I-UdRmethod and the results were compared to the estimates for cell loss as determined by the combined approach of cellular ³H-TdR autoradiography and volumetric growth-rate determinations. This detailed comparison shows that the two methods complement each other but cannot substitute for one another because they give different quantitative information. The combined approach measures the flow of viable cells, as determined morphologically, from the proliferating compartment to the quiescent compartment, the quiescent compartment out of the tumor, etc., but does not evaluate the flow of degenerate cells or acellular (necrotic) debris. In contrast, the ¹²⁵I-UdR method indicates the net flow of intact cells and/or dead cells as well as debris from the tumor as the ^I25l-labeled material is lost from the tumor, but gives limited internal information. Thus, depending on the specific experiment, an investigator could choose one or the other of the methods to answer the question. Perhaps both would be desirable at times; however, in most cases, one could not substitute one method for the other. The data from the Slow tumors also indicate that in certain tumors, the quantitative information from the ¹²⁵I-UdR method may be quite limited, i.e. the confidence limits within an experiment as well as the replication error between experiments may be high.     

Levels of selected growth factors in viable and necrotic regions of xenografted HCT-8 human colon tumours

Xenografted tumours were produced in nude mice by injection of HCT-8 human colon tumour cells. At average volumes of about 750 mm³, animals were injected with fast green vital dye, and 20 min later, tumours were excised and dissected into viable (stained) and necrotic portions (unstained). Viable and necrotic regions were then examined for cell yields, colony forming efficiencies, and levels of basic fibroblast growth factor (FGF-2), transforming growth factors-β₁ and -α (TGF-β₁, TGF-α), platelet derived growth factor (PDGF), and vascular endothelial growth factor (VEGF) using enzyme-linked immunoassay (ELISA) procedures. Levels in the viable and necrotic regions were compared to levels in unseparated tumours. The average extent of necrosis in HCT-8 tumours of this size was 64%. The data for cell yields, colony forming efficiencies FGF-2, VEGF, TGF-β₁ and TGF-α indicated that values determined in the unseparated tumours could be understood on the basis of the weighted average between viable and necrotic tissue, with the higher values occurring in the viable tissue. Low levels of FGF-2 and VEGF were found in the necrotic portions of the tumour while no measurable levels of TGF-β₁ and TGF-α could be determined. PDGF levels were, however, equivalent in both the viable and necrotic regions indicating that necrotic tissue could be an important reservoir for this growth factor.     

Changes in the extents of viable and necrotic tissue, interstitial fluid pressure, and proliferation kinetics in clone A human colon tumour xenografts as a function of tumour size

Abstract. Total, viable and necrotic tumour tissue, tumour cell yields, and colony forming efficiencies were measured in clone A human colon tumour xenografts as neoplasms grew from about 100 mm³ to about 6000 mm³. The volumes of the total, viable and necrotic compartments were fit using the Verhulst equation to obtain estimates of growth rates and maximal sizes of the various compartments (carrying capacities). Additionally, at four discrete tumour volumes (250, 850, 2500 and 5500 mm³), hypoxic percentages, proportions of parenchymal tumour and host cells, interstitial fluid pressures, and proliferation kinetics including measurements of apoptosis were determined. There were interesting relationships between the shapes of the curves for total, viable and necrotic tissue to some of the other endpoints measured. Specifically, the volumetric growth curves for the total and viable tumour tissue compartments were identical to a volume of approximately 1000 mm³, but diverged at larger sizes, with the viable cell compartment exhibiting a smaller carrying capacity. The shape of the growth curve for the necrotic compartment exactly mimicked that for the total volume compartment, but was delayed in time by about 21 days. Similarity in shape to that of the overall tumour volume/necrotic volume curves was also seen for the curve for the increase in interstitial fluid pressure, and for the increase in the size of the host cell compartment. In contrast, the growth of the hypoxic compartment and of the parenchymal tumour cell compartment were similar in shape to that of the viable compartment. These data indicate that these compartments are functionally linked. Marked changes in cell kinetic parameters occurred as tumour size increased from 250–5500 mm³. The labelling index and growth fractions decreased from 0.256–0.125, and 0.77–0.40 respectively, and the cell loss factor increased from 0.52–0.74. The volumetric and potential doubling times increased from 4.3–17.6 and 2.1–4.6 days respectively. The cell kinetic changes could not be clearly related to the changes in shape of either the overall tumour volume or the viable tumour volume.     

Simultaneous analysis of radio-induced membrane alteration and cell viability by flow cytometry

BACKGROUND: Modifications of intracellular transfer, resulting from a loss of membrane integrity may contribute toward setting the cell onto the pathway of apoptosis. METHODS: We have developed an original technique of measuring simultaneously, with flow cytometry, changes in membrane fluidity and cell death status. Our aim was to assess the extent to which radio-induced cell death and membrane alterations are linked. Investigations were performed on lymphocytes 24 h after whole human blood gamma-irradiation. RESULTS: Our results confirmed the expected increase in the percentage of apoptotic cells as a function of dose, but revealed that the percentage of necrotic cells appeared stable after irradiation. At the same time, the fluorescence anisotropy of the living lymphocyte subpopulation decreased significantly and dose dependently as measured 24 h post-irradiation. With TMA-DPH, the anisotropy index of apoptotic lymphocytes was always lower than that of the viable lymphocyte subpopulation. On the other hand, 1,6-diphenyl-1,3,5-hexatriene (DPH) anisotropy was similar in apoptotic and viable cells after irradiation. These findings suggest that apoptotic lymphocytes are characterised by a membrane fluidization that mainly occurs on the cell membrane surface. CONCLUSION: Our study made technical advances in using cytometric fluorescence anisotropy measurement as an early biological indicator of apoptosis after cellular exposure to ionising radiation.     

125I-UdR提高内皮抑素基因的抑瘤作用

目的：探讨125I-UdR提高内皮抑素基因对大鼠种植癌模型的抑制效应。方法：制作肿瘤株Walker-256细胞大鼠皮下种植癌的动物模型并分为1-4组（对照组、125I-UdR组、Endostatin组和Endostatin＋125I-UdR组）,每组20只,通过实体瘤内注射,分别给与相同体积生理盐水125I-UdR、内皮抑素基因及125I-UdR和内皮抑素基因混合物,测量肿瘤治疗前体积（V0）和治疗后不同时间体积（Vt）,计算10d、20d的肿瘤生长率（f=Vt／V0）,观察各组肿瘤在光镜下的变化。结果：各组大鼠10d、20d肿瘤生长率为：（11．03±1．08、27．35±1．08）,（4．02±0．79、7．58±2．98）,（3．88±0．26、7．02±2．75）,（2．72±1．01、2．94±1．26）,2、3、4组的肿瘤生长率明显小于l组（P〈0．001）;2、3组之间肿瘤生长率差别不明显（P〉0．05）,4组肿瘤生长率小于2、3组（P〈0．01）.结论：通过实体瘤内注射的方法给与125I-UdR、内皮抑素基因及两者混合物后,能够明显抑制肿瘤的生长,内皮抑素基因和125I-UdR联合治疗在抑制肿瘤生长方面作用更加显著。     

Effect of dexamethasone on uterine cell death

Oestrogen, progesterone and androgen inhibit uterine cell death after the depletion of oestrogen. In the present study, we investigated effects of glucocorticoid on death of mouse uterine cells. Castrated female mice were given a daily injection of 17 beta-oestradiol (0.2 microgram/mouse/day) for 3 days, and then an injection of 5'-[125I]iodo-2'-deoxyuridine ([125I]IdUrd) to label DNAs of uterine cells with 125I. Mice were killed at intervals during subsequent treatments, and the retention of [125I]IdUrd incorporated into the whole uterus was determined. On subsequent injection of vehicle only, the 125I-radioactivity retained in the whole uterus rapidly decreased. Injections of dexamethasone (50 micrograms/mouse/day) reduced the loss of 125I-radioactivity slightly but significantly. Dexamethasone also showed synergistic effects on the retention of 125I-radioactivity when it was daily injected together with 17 beta-oestradiol, progesterone or 5 alpha-dihydrotestosterone. The present results suggest that glucocorticoid may affect the processes involved in the uterine cell death, in a manner such as inhibiting the uterine cell death or delaying the removal of DNAs of dead cells from the uterus.     

DIFFERENT ACTION OF SUICIDAL DOSES OF TRITIATED THYMIDINE AND HYDROXYUREA ON MURINE HAEMOPOIETIC CELLS

In order to gather information on the factors that cause the different action of suicidal doses of tritiated thymidine (³H-TdR) and of hydroxyurea on murine stem cells, the incorporation of ³H-TdR into DNA of bone marrow and spleen cells has been studied. Continuous death of labelled cells after suicidal ³H-TdR is indicated by a more pronounced decline of total DNA-bound radioactivity in bone marrow and spleen cells compared to that in control animals which had received tracer doses of ³H-TdR. Extensive and rapid loss of DNA-bound radioactivity occurred in ³H-TdR labelled animals after hydroxyurea treatment indicating an instantaneous and highly effective killing of labelled cells. After double labelling of DNA with ³H-TdR and ¹²⁵iodo-deoxyuridine (¹²⁵I-UdR), the decline of the ratio of DNA-bound ¹²⁵I to DNA-bound ³H after suicidal ³H-TdR indicates prolonged tritium reutilization. Following hydroxyurea, reutilization was completed within the first 12 hr after drug administration. These findings explain in part the slow recovery of different stem cell compartments after suicidal ³H-TdR on the basis of protracted tritium reutilization as compared to the fast recovery which follows the rapid action of hydroxyurea.     

[3H]thymidine labels less than half of the DNA-synthesizing cells in the mouse tumour, carcinoma NT

Abstract. We have studied carcinoma NT, a transplantable mouse adenocarcinoma of spontaneous origin. Cells labelled with [³H]thymidine ([³H]TdR) were restricted to a narrow zone around the periphery of this tumour and were also found in rings up to 50 μ m wide, around isolated blood vessels in the central necrotic area. Labelling with [³H]deoxyuridine ([³H]UdR), another DNA synthesis precursor, produced a very different pattern. The labelled zone around the periphery was much wider than with [³H]TdR, and [³H]UdR labelled cells were found up to 110 μ m from isolated vessels. [³H]iododeoxyuridine ([³H]IUdR) gave the same pattern of labelling as [³H]UdR. In the heavily labelled zone, within 1 mm of the tumour periphery, the labelling index (LI) was 51% after [³H]UdR or [³H]IUdR injection, and only 36% with [³H]TdR.
The data show that at least half of the DNA-synthesizing cells in this tumour did not incorporate [³H]TdR. Previous workers reported cell loss factors for carcinoma NT of 60% calculated from [³H]TdR labelling data and 30% from the rate of loss of [¹²⁵I]UdR. The present work suggests that calculations based on [¹²⁵I]UdR data are more likely to be accurate for carcinoma NT than those using [³H]TdR data.     

Modelling the formation of necrotic regions in avascular tumours

The mechanisms underlying the formation of necrotic regions within avascular tumours are not well understood. In this paper, we examine the relative roles of nutrient deprivation and of cell death, from both the proliferating phase of the cell cycle via apoptosis and from the quiescent phase via necrosis, in changing the structure within multicellular tumour spheroids and particularly the accumulation of dead cell material in the centre. A mathematical model is presented and studied that accounts for nutrient diffusion, changes in cell cycling rates, the two different routes to cell death as well as active motion of cells and passive motion of the dead cell material. In studying the accumulation of dead cell matter we do not distinguish between the route by which each was formed. The resulting mathematical model is examined for a number of scenarios. Results show that in many cases the size of the necrotic core is closely correlated with low levels in nutrient concentration. However, in certain cases, particularly where the rate of necrosis is large, the resulting necrotic core can lead to regions of non-negligible nutrient concentration-dependent upon the mode of cell death.     

Ultrastructural identification of apoptotic nuclei using the TUNEL technique

Summary We describe an ultrastructural adaptation of the method of terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labelling (TUNEL) for the identification of DNA fragmentation. Thin sections of tissue embedded in hydrophilic resin were nick end labelled with biotinylated dUTP which was subsequently labelled with avidin conjugated to gold particles. The technique was validated by labelling the nuclei of L929-8 cells treated with tumour necrosis factor α. These cells are known to respond to treatment with the factor by undergoing apoptosis. The method was then used on tissue from the chick embryo which is known to be undergoing programmed cell death. This tissue was from the neural tube and the posterior necrotic zone of the limb bud, where cells can be identified as undergoing apoptosis based on the morphology of their nuclei. The method specifically labelled heterochromatin adjacent to the nuclear envelope as well as the associated with the nucleolus of cells from regions of the embryo where programmed cell death was expected. In addition to labelling the nuclei of cells that were clearly undergoing apoptosis, the method also identified nuclei of apparently normal cells. This method, used in conjunction with corroborating techniques, provides a means for the early detection of cells undergoing DNA fragmentation, before the onset of gross apoptotic morphology, and in cells that do not show classical apoptotic characteristics.     

Suppressive effect of adrenalectomy on growth of L1210 leukemic cells in ascites

This study was designed to evaluate the effect of adrenalectomy on growth of L1210 leukemic cells in ascites of BDF1 mice. Varying doses of 1.5 x 10(4), 5.0 x 10(5), and 1.5 x 10(6) viable tumour cells were inoculated intraperitoneally into groups of either adrenalectomized or sham-operated mice. At days 4 to 7 after the inoculation, adrenalectomized mice inoculated with 1.5 x 10(4) or 5.0 x 10(5) tumour cells had a smaller number of tumour cells in ascites than sham-operated controls. However, after inoculation of 1.5 x 10(6) cells, no significant differences were found at days 2 to 4 between adrenalectomized and sham-operated mice. The growth retardation by adrenalectomy was not observed in adrenalectomized mice supplemented with 4 or 6 micrograms dexamethasone per day per mouse. It suggested that the ablation of glucocorticoids was at least partially responsible for the growth retardation observed in adrenalectomized mice. Cell kinetic analysis revealed that the difference in a potential doubling time could not explain these results. Tumour retention in the peritoneal cavity was measured using [125I]-iododeoxyuridine-labelled tumour cells as a tracer. At days 4 to 6 after inoculation of 5.0 x 10(5) labelled cells, radioactivity in the peritoneal cavity in adrenalectomized mice was about 70 per cent of that in sham-operated mice. This ratio was almost equivalent to the ratio of the number of cells in ascites of adrenalectomized mice to that of sham-operated ones. Consequently, growth retardation observed in adrenalectomized mice resulted from an increase in tumour cell migration and/or in tumour cell death, but not from an increase in doubling time.     

Cell kinetics methods for clinical use: assessment of autoradiography and 125I-iodo-deoxyuridine with mouse Ehrlich tumour.

Superficial Ehrlich tumours in mice were used to assess how much information on cell kinetics could be obtained from only the simplest techniques of autoradiography, and in situ monitoring of 125I-iodo-deozyuridine. These techniques were selected as being readily applicable to clinical situations. Intradermal tumours were studied from the earliest stages of rapid growth to large slow growing tumours with necrotic cores, as well as tumours undergoing regression. For comparison, intramuscular tumours were studied with systemic injections of radioactive DNA precursors. It was found that extensive information on cell production and loss rates was obtained from a single injection of tritiated thymidine followed by a single biopsy, or alternatively in vitro labelling of one minute biopsy specimen, and measurements of only the labelling index, together with a knowledge of the tumour's growth characteristics. Following a single localized injection of 125I-iodo-deoxyuridine, the loss rate of radioactivity measured in situ for a period of about 1 week provided an index of cell loss rate from the tumours.     

Amplification of oncogenes and integrated SV40 sequences in mammalian cells by the decay of incorporated iodine-125

Iodine-125, in the form of 5-[125I]iododeoxyuridine (I-UdR), was incorporated into the DNA of SV40 transformed Chinese hamster embryo cells. Disintegration of the 125I led to increased cell killing with increasing dose as measured by the colony-forming ability of single cells. The D37 (the dose at which 37% of the cells survive) amounts to 95 decays per cell, corresponding to 0.66 Gy. Variations in the copy number of specific DNA sequences was measured by using dispersed cell blotting with sensitive DNA hybridizations. A 13-fold amplification of the viral DNA sequences (SV40) and a twofold amplification of two cellular oncogenes of the ras-family (Ki-ras and Ha-ras) were found. Other cellular genes, like the alpha-actin gene, were not amplified, and no variation in gene copy number was detected after incubation of cells with cold I-UdR. We suggest the observed gene amplifications are induced by the densely ionizing radiation emitted by the decay of the incorporated 125I atoms.     

Inhibitory effect of androgen on cell death of mouse uterine epithelium

The protective effect of androgen against the cell death of mouse uterine epithelium was evaluated by examining the retention of 5'-[125I]iodo-2'-deoxyuridine ([125I]IdUrd) incorporated into the whole uterus and the apoptotic index (percentage of the apoptotic cells to the total cells) which is a good index of physiological cell death. Castrated adult female mice were daily injected with oestradiol-17 beta for 3 days, followed by the injection of [125I]IdUrd. Thereafter, these mice were daily injected with only the vehicle or 5 alpha-dihydrotestosterone (DHT), and the 125I-radioactivity retained in the whole uterus was determined. When only the vehicle was injected, the 125I-radioactivity retained in the whole uterus rapidly decreased but injections of DHT reduced the loss of 125I-radioactivity. The effect of DHT on the retention of 125I-radioactivity depended on doses of DHT and was abolished by the pure antiandrogen, flutamide. The apoptotic index of uterine cells was examined by a similar experimental protocol, but without an injection of [125I]IdUrd. Injections of only the vehicle caused marked increases in the apoptotic indices of both luminal and glandular epithelia, but injections of DHT decreased them significantly. The apoptotic index of stroma was not affected by the injection of DHT. The present results indicated that androgen reduces the cell death of mouse uterine epithelium through the androgen receptor.     

Inhibitory effect of progesterone on cell death of mouse uterine epithelium

The protective effect of progesterone against cell death of mouse uterine epithelium was evaluated by examining the retention of 5'-[125I]iodo-2'-deoxyuridine [( 125I]IdUrd) incorporated into the whole uterus and the apoptotic index (percentage of apoptotic cells in total cells), which is a good index of physiological cell death. Castrated adult female mice were given a daily injection of oestradiol-17 beta for 3 days, and then an injection of [125I]IdUrd. They were then divided into 4 groups, which received a daily injection of vehicle only, oestradiol-17 beta (E), progesterone (P), or both oestradiol-17 beta and progesterone (EP), and were killed at intervals during these treatments for determination of 125I radioactivity retained in the whole uterus. On treatment with vehicle only, the 125I radioactivity retained in the uterus decreased rapidly, but treatment with E, P or EP reduced the loss of 125I radioactivity significantly. Progesterone did not antagonize the effect of oestradiol-17 beta on the 125I radioactivity retained in the uterus. The apoptotic index of uterine cells was examined by a similar experimental protocol, but without injection of [125I]IdUrd. In the group treated with vehicle only, the apoptotic indices of both luminal and glandular epithelia increased markedly, but the injection of E, P or EP suppressed these increases significantly. Progesterone did not antagonize the effect of oestradiol-17 beta on the apoptotic index. The apoptotic index of stroma was not affected by the injection of E, P or EP. On the other hand, progesterone completely inhibited the increase in the mitotic index of uterine epithelia induced by oestradiol-17 beta. These results show that progesterone alone or in combination with oestrogen reduced cell death in mouse uterine epithelium and that the effects of oestrogen and progesterone on uterine cell death were independent of their actions on cell division.