CHARACTERISTICS OF THE ISOPRENALINE STIMULATED PROLIFERATIVE RESPONSE OF RAT SUBMAXILLARY GLAND

A simple stochastic model has been developed to determine the cell cycle kinetics of the isoprenaline stimulated proliferative response in rat acinar cells. The response was measured experimentally, using ³H-TdR labelling of interphase cells and cumulative collections of mitotic cells with vincristine. The rise and fall of the fraction of labelled interphase cells and of metaphase cells is expressed by the product of the proliferative fraction and a difference of probability distributions. The probability statements of the model were formulated and then compared by an iterative fitting procedure to experimental data to obtain estimates of the model parameters. The model when fitted to the combined fraction labelled interphase (FLIW) and fraction metaphase (FMW,) waves gave a mean G_is transit time of 21-2 hr, mean G_is+ S transit time of 270 hr, and mean G_is+ S + G₂ transit time of 35-8 hr for a single injection of isoprenaline, where G_is is the initiation to S phase time. When successive injections of isoprenaline were given at intervals of 24 and 28 hr the corresponding values after the third injection were 12-4 hr, 20-8 hr and 25-7 hr respectively. The variance of the G_is phase dropped from 18-1 to 1–3 while the other variances remained unchanged. The estimated proliferative fraction was 0–24 after a single injection of isoprenaline, and 0–31 after three injections of the drug. Independently determined values of the proliferative fraction, obtained from repeated ³H-TdR injections, were 0–21 and 0–36 respectively.     

RECYCLING OF RESTING CELLS IN THE JB-1 ASCITES TUMOUR AFTER TREATMENT WITH 1-β-D-ARABINOFURANOSYLCYTOSINE (Ara-C)

Resting cells in tumours present a major problem in cancer chemotherapy. In the plateau phase of growth of the murine JB-1 ascites tumour (i.e. 10 days after 2–5 × 10⁶ cells i.p.) large fractions of non-cycling cells with G₁ and G₂ DNA content (Q₁ and Q₂ cells) are present, and the fate of these resting cells was investigated after treatment with l-β-d-arabinofuranosylcytosine (Ara-C). The experimental work consisted of growth curves, percentage of labelled mitoses curves after continuous labelling with ³H-TdR, and cytophotometric determination of single-cell DNA content in unlabelled tumour cells. Treatment with an i.p. single injection of Ara-C 200 mg/kg in the plateau JB-1 tumour resulted in a significant reduction in the number of tumour cells 1 and 2 days later as compared with untreated controls, while no difference in the number of tumour cells was observed after 3 days. In tumours prelabelled with ³H-TdR 24 hr before Ara-C treatment, a significant decrease in the percentage of labelled mitoses was observed 6–8 hr later followed by a return to the initial value after 12 hr, and a new pronounced fall from 20 hr after Ara-C. The second fall in the percentage of labelled mitoses disappeared when the labelling with ³H-TdR was continued also after Ara-C treatment. Cytophotometry of unlabelled tumour cells prelabelled for 24 hr with ³H-TdR before Ara-C treatment showed 20 hr after Ara-C a pronounced decrease in the fraction of Q_t cells paralleled by an increase in the fraction of unlabelled cells with S DNA content. These results indicate recycling of resting cells first with G₂ and later with G_x DNA content, which contribute to the regrowth of the tumours.     

AUTOSYNCHRONIZATION OF RAT LIVER CELLS WITH ENDOGENOUS CORTICOSTERONE AFTER PARTIAL HEPATECTOMY

After adrenalectomy in adult male rats ³H-TdR incorporation into the liver parenchymal cells is increased 4–8 times and the mitotic index rises from 0–31 % to 1–3%; this is inhibited by corticosterone. After hepatectomy the serum corticosterone level increases from 18 μg/100 ml to 57 μg/100 ml. The corticosterone binding capacity of the serum declines from 2–06 to 0–17. The activity of tyrosine transaminase doubles, whereas the incorporation of ³H-TdR into the liver cells is decreased by a factor of 5–7. Thereafter the binding capacity increases again and reaches, 24 hr after operation, a value of 3–82. The tyrosine transaminase activity and the serum corticosterone content return to normal. ³H-TdR incorporation, however, increases by a factor of 7-7 of the initial value. We concluded that in the first few hours after partial hepatectomy corticosterone blocks the liver cells in G₁ and an accumulation of the cells occurs at this cell cycle phase. Folio wing the binding of the corticosterone by serum proteins a little later the liver cells enter the S-phase synchronously.     

Low-dose methotrexate enhances cycling of highly anaplastic cancer cells

We previously showed that cellular RedOx state governs the G₁-S transition of AH130 hepatoma, a tumor spontaneously reprogrammed to the embryonic stem cell stage. This transition is impaired when the mithocondrial electron transport system is blocked by specific inhibitors (antimycin A) or the respiratory chain is saturated by adding to the cells high concentrations of pyruvate. The antimycin A or pyruvate block is removed by the addition of adequate concentrations of folate (F). This suggests that the G₁-S transition of AH130 cells depends on a respiration-linked step of DNA synthesis related to folate metabolism. In the study reported here, we characterized the effects of methotrexate (MTX), an inhibitor of dihydofolate-reductase, on the G₁-S transition of hepatoma cells, in the absence or the presence of exogenously added F, dihydrofolate (FH₂) or tetrahydrofolate (FH₄). MTX, at 1 μM or higher concentrations, inhibited G₁-S transition. This inhibition was completely removed by exogenous folates. Surprisingly, 10 nM MTX stimulated G₁-S transition. The addition of F, but not FH₂ or FH₄, significantly increased this effect. Furthermore, 10 nM MTX removed the block of the G₁-S transition operated by antimycin A or pyruvate, an effect which was enhanced in the presence of F. Finally, the stimulatory effect of 10 nM MTX was inhibited in the presence of serine. Our findings indicated that, under certain conditions, MTX may stimulate, rather than inhibiting, the cycling of cancer cells exhibiting a stem cell-like phenotype, such as AH130 cells. This may impact the therapeutic use of MTX and of folates as supportive care.     

Cyclic adenosine monophosphate acts synergistically with dexamethasone to inhibit the entrance of cultured adult rat hepatocytes into S-phase: with a note on the use of nucleolar and extranucleolar [3H]-thymidine labelling patterns to determine rapid changes in the rate of onset of DNA replication

Analogs of cyclic adenosine monophosphate (cAMP) (N⁶benzoyl cAMP and N⁶monobutyryl cAMP) as well as agents that increased the intracellular level of cAMP (glucagon and isobutylmethylxanthine) inhibited the EGF-stimulated DNA replication of adult rat hepatocytes in primary culture independently of cell density. This inhibition was strongly potentiated by the glucocorticoid dexamethasone. The effect of cAMP (and dexamethasone) was not due to toxicity, because the inhibition was reversible and the cell ultrastructure preserved. cAMP acted by decreasing the rate of transition from G₁- to S-phase, the duration of G₂- and S-phase of the hepatocyte cell cycle being unaffected. DNA replication started in the extranucleolar compartment of the nucleus and ended in the nucleolar compartment as described earlier for cells grown in the absence of cAMP (O.K. Vintermyr and S.O. Døskeland, J. Cell. Physiol., 1987, 132:12-21). The action of cAMP was very rapid: significant inhibition of the transition was noted 2 hr after the addition of glucagon/IBMX and half-maximal inhibition after 4 hours. The determination of extranucleolarly labelled nuclei in cells pulse-labelled with [³H]thymidine allowed precise analysis of rapid changes in the probability of transition from G₁- to S-phase. The extranucleolar labelling index could also be determined in cells continuously exposed to [³H]thymidine.     

Epidermis Extracts (Chalone) Inhibit Cell Flux At the G1-S, S-G2 and G2-M Transitions In Mouse Epidermis

Epidermal cell flux at the G₁-S, S-G₂ and G₂-M transition was examined during the first 4 hr after injection of epidermis extract. the flux parameters were estimated by a combination of several methods. the G₁-S and S-G₂ transit rates were calculated on the basis of a double labelling technique with [³H]TdR, the G₂-M flux by means of colcemid and the relative proportion of cells in the S or G₂ phase by means of flow cytometry. All experiments were performed both in early morning and late evening, corresponding to maximum and minimum rates of epidermal cell proliferation in the hairless mouse. the epidermis extract inhibited the S-G and G₂-M transit rates to the same degree, while the inhibition of cell flux at the G₁-S transit was consistently stronger. In general, the inhibition of cell flux at the different transitions was most pronounced when the rate of cell proliferation was low and vice versa.     

CYTOKINETICS OF RAT TRACHEAL EPITHELIUM STIMULATED BY MECHANICAL TRAUMA

Mild abrasion of rat tracheal epithelium results in irreversible damage to the superficial cells and stimulates the viable basal cells to participate in a nearly synchronous wave of DNA synthesis and mitosis. For the growth population as a whole, DNA synthesis started at 14 hr after injury and persisted for 16 hr. The duration of S in individual cells was determined autoradiographically by identifying the time at which a second pulse of DNA precursor (¹⁴C-TdR) was no longer incorporated by cells labelled with ³H-TdR at the onset of S. S was found to be 8–9 hr long. It was also determined that cells entering S at later times synthesized DNA for the same 8–9 hr period. T_G2 was calculated to be 21/2–31/2 hr by subtraction of T_s and 1/2T_M from the period from onset of DNA synthesis to metaphase. By making a second denuding lesion adjacent to the first injury, the cells were stimulated through at least another period of S. At the peak of the second wave of DNA synthesis (50 hr after injury) ¹⁴C-TdR was present in the same cells which had incorporated ³H-TdR administered at the mid-point of the preceding synthetic phase. The 28-hr interval between these two peaks of synthesis is the measure of cell cycle duration for these regenerating tracheal epithelial cells.     

ANALYSIS OF THE GROWTH KINETICS OF A HUMAN LYMPHOMA CELL LINE

The growth kinetics of an established human lymphoma cell line were analyzed by a variety of techniques utilizing various cell inocula (5 x 10⁴ - 5 x 10⁵ cells) dispensed into 60 mm diameter dishes. Techniques included pulse-labeled mitosis (PLM), continuous labeling with ³H-TdR, time-lapse photography (TLP), cell counts by electronic particle counter, and DNA histography obtained by pulse cytophotometry (PCP). There were no significant differences among values determined for any kinetic parameters as a function of cell concentration. the average doubling time of exponentially growing cells, regardless of cell inoculum, was 44.1 hr. the generation time determined by PLM was 31.1 hr with a SD of 4.7 hr. Transit times for each stage were: T_G1= 10.6 hr, T_s= 9.9 hr, T_G2= 9.9 hr, and T_m= 0.7 hr. Repeated experiments using continuous labeling with ³H-TdR demonstrated a T_G2 of 6.3 hr. the longer value determined by PLM is possibly due to the technical manipulations of this procedure which may delay pulse-labeled cells from resuming cell cycle transit. Hence, values for cell cycle stages were recalculated to give T_G1= 14.1 hr, T_s= 9.9 hr, T_G2 = 6.3 hr, and T_m= 0.7 hr. These results were used to compute the size of each cell cycle stage compartment pool and corresponded very closely to values defined directly by PCP. TLP analysis considered only cells that produced colonies of at least thirty-two cells. Generation times ranged from 8 to 89 hr and showed a positive skewness. the average value measured for 330 divisions was 34.5 hr with a SD of 13.2 hr. Thus, the variance predicted by curve fitting of the PLM data did not correlate with that defined by time-lapse photography nor did it encompass the range in generation times observed directly by TLP. There was a positive correlation between sister-sister cell generation times (+0.66) but no relation was noted for mother-daughter values.     

EFFECTS OF BLEOMYCIN ON THE EPIDERMAL CONTENT OF GROWTH-REGULATORY SUBSTANCES (CHALONES)

Hairless male mice were given 2 mg Bleomycin i.p. on two successive days. At different time intervals from 1 to 10 days after the last Bleomycin injection, groups of animals were killed and water extracts of homogenized skin were made. These extracts, supposed to contain the epidermal G₁ and G₂ chalones, were injected into female hairless mice, and their growth inhibitory potency determined by two methods. 5 mg of lyophilized crude skin extract were injected i.p. together with Colcemid, and the animals killed 4 hr later. The number of Colcemid-arrested mitoses was determined, and was considered to be a measure of the G₂ inhibitor present in the skin extracts. 10 mg of the same extracts were injected i.p., and these animals also got ³H-TdR i.p. 12 hr later, and were killed after a subsequent 30 min. The epidermal LI was determined, and was considered to be a measure of the epidermal G₁ factor in the skin extracts. The results obtained were compared to the effect of Bleomycin alone and to the effects of skin extracts from non-Bleomycin-treated animals. The results show that Bleomycin provoked slight alterations in the growth-inhibitory potency of the G₁ chalone, whereas significant effects were seen in the G₂ chalone. There was an increased amount of growth-inhibiting factors on days 2 and 3, and on days 8–10. The results are discussed and it is concluded that the most probable hypothesis is that Bleomycin, in addition to its known inhibitory effect on epidermal cell proliferation, exerts growth inhibition by accumulation of cells with high growth inhibitory potency. An initial, additional direct effect of Bleomycin on the chalone system cannot be excluded.     

THE INFLUENCE OF INJECTED TRITIATED THYMIDINE ON THE MITOTIC CIRCADIAN RHYTHM IN THE EPITHELIUM OF THE HAMSTER CHEEK POUCH*

The initial effect of an injection of TdR-5-³H (1 μCi/g body weight; 6 Ci/mmol) in the cheek pouch epithelium of the Syrian hamster is an increase in the mitotic index. The increase is observed 1–5 hr after injection, depending upon the time of day when the injection is given, and is followed by compensatory variations in mitotic index. This deviation from the normal circadian rhythm in the mitotic index appears to depend on the fraction of G₂-cells at the time of injection. The main effect is a shortening of t_g2. No effect is observed after injection of non-radioactive TdR or isotonic saline. The results of the present experiment emphasize that unexpected results may be obtained when using mitotic indices from animals labelled with ³H-TdR, as well as the risks of using the PLM-method in a partially synchronized system.     

Circadian-Stage Dependence of Methotrexate In A Keratinized Epithelium. an in-vivo Study Using Flow Cytometry On the Hamster Cheek Pouch Epithelium

The partially synchronized cell system of the hamster cheek pouch epithelium shows a characteristic diurnal rhythm of cell proliferation. Bolus injections of methotrexate (Mtx) in both lethal (10 g/m²) and non-lethal (2 g/m²) doses were found to inhibit cell-cycle progression primarily by impairing the G₁/S transition. the results were obtained by flow cytometric DNA analysis. the inhibitory effect of Mtx manifested itself as a relative decrease of the S fraction (drug-effector phase), and was found to be dependent both on the dose and on the time of the day it was given. A bolus injection of Mtx was given either at 1200 hr (when a minimal number of cells are in S phase) or at 0200 hr (when a maximum number of cells are in S phase). the greatest cumulative decrease in S fraction was seen when the injection was given at 1200 hr. the time between injection and the effect (seen as a decrease in S fraction) was independent of the time of the Mtx injection, but seemed instead to be related to the natural diurnal period of increasing flux from G₁ to S phase (at the onset of the dark period). the main effect (the relative decrease in S fraction) was repeated during the following 24-hr period, pointing to a protracted effect of Mtx on G₁ cells. G₁ cells affected by the initial high Mtx plasma concentration seem to be responsible for the reduced influx into S phase in both the first and second 24-hr period. In earlier toxicological studies, the survival rate of hamsters was dependent on the time of injection and was highest after injection at 1200 hr. Thus maximum cytokinetic effect on epithelial cells was found at the time of the day when there was a minimum lethal effect on the animal.     

Chromosomes and DNA-replication of rat kangaroo cells (PtK2)

The karyotype, chromosomal measurements, and the time course of DNA replication during the S-phase were determined in metaphase chromosomes of non-synchronized monolayer cultures of PtK₂ cells (CCL 56) derived from Potorous tridactylis. The karotype was the same as originally determined for this cell line. Chromosomal measurements differed from data for primary bone marrow cells of this species published by Shaw and Krooth. PtK₂ cells and chromosomes showed maximal incorporation of tritiated thymidine (³H-TdR) halfway through the S-phase. Chromosome Y₁ showed a second peak of ³H-TdR-incorporation at the end of the S-phase in addition to the peak halfway through S. Comparison of grain densities for chromosomal arms showed late replication of the short arms of chromosomes 1, 3, and X. The time course of incorporation of ³H-TdR was changed when cells were treated for 1 h with fluorodeoxyuridine (FUdR) prior to the ³H-TdR-pulse. FUdR-treated cells showed maximum incorporation of ³H-TdR immediately after the beginning of the S-phase, which was followed by a second peak halfway through the S-phase. This indicated that ³H-TdR-incorporation was partially synchronized by treatment of cells with FUdR. Total radioactivity of FUdR-treated cells had increased by 77% in comparison to cells not treated with FUdR, which indicates that approximately 44% of the TdR-precursors of the latter cells may have originated from cellular precursor pools.     

Rates of incorporation of radioactive molecules during the cell cycle

We report measurements of the incorporation of radioactive molecules during short labeling periods, as a function of cell-cycle stage, using a cell-sorter-based technique that does not require cell synchronization. We have determined: (1) tritiated thymidine (³H-TdR) incorporation throughout S-phase in Lewis lung tumor cells in vitro both before and after treatment with cytosine arabinoside; (2) ³H-TdR incorporation throughout S-phase in KHT tumor cells in vitro and in vivo; (3) ³H-TdR incorporation throughout S-phase in Chinese hamster ovary cells and compared it with DNA synthesis throughout S-phase; (4) a mathematical expression describing ³H-TdR incorporation throughout S-phase in Chinese hamster M3-1 cells; and (5) the simultaneous incorporation of ³H-TdR and ³⁵S-methionine as they are related to cell size and DNA content in S49 mouse lymphoma cells. In asynchronously growing cells in vitro and in vivo, ³HH-TdR incorporation was generally low in early and late S-phase and highest in mid-S-phase. However, in Lewis lung tumor cells treated with cytosine arabinoside ³H-TdR incorporation was highest in early and late S-phase and lowest in mid-S-phase. Incorporation of ³⁵S-methionine increased continuously with cell size and DNA content. Incorporation of ³H-TdR in CHO cells was proportional to DNA synthesis.     

PROPERTIES OF G0 CELLS: VARIATIONS IN THE PROLIFERATIVE RESPONSE FOLLOWING ISOPRENALINE

The proliferative behaviour induced in the acinar cells of the rat submaxillary gland in response to isoprenaline has been used to examine the transit time of cells from a quiescent (G₀) state into the S phase. Cumulative ³H-TdR labelling index curves were constructed to determine the mean time interval (G_is time) between stimulation with isoprenaline and entry into the S phase. Data were collected for the proliferative wave induced by three sequential injections of isoprenaline, and the effects of varying the interval between the second and third injections of isoprenaline, and of changing the dose of the drug, were examined. Intervals of 28, 52 and 76 hr between isoprenaline injections resulted in mean G_is times of 16-2, 20-9 and 25-6 hr respectively. It was concluded that the G_is time depended on the recent history of cells with respect to stimulation, but not division. The results are considered in terms of two models, in one of which the time to leave G₀ is variable, whilst in the other the cells leave G₀ immediately the stimulus is applied.     

NUCLEOCYTOPLASMIC RATIO REQUIREMENTS FOR THE INITIATION OF DNA REPLICATION AND FISSION IN TETRAHYMENA

Hydroxyurea (10 mM) arrests the exponential growth of Tetrahymena by blocking DNA replication during S-phase. After removal of the hydroxyurea (HU), they have a long recovery period during which they are active in DNA synthesis. ³H-TdR uptake showed that on completion of the recovery period, the cells divide (recovery division) and enter a cell cycle which lacks G₁. The frequency, size and DNA content of the extranuclear chromatin bodies (ECB) formed at this division are all markedly increased (2–4) over the corresponding values obtained from exponential growth phase controls. Microspectrophotometric analysis of macronuclear DNA content (N) coupled with the cytoplasmic dry mass (C) values suggest that specific N to C ratios (N/C) are required for the initiation of DNA replication and fission: during a normal (exponential growth) cell cycle, both N and C double, but asynchronously, so that the N/C of both post-fission-daughter cells and pre-fission cells is identical (standardized to N/C = 1) but late G₁ cells have a low N/C. During a 10 hr exposure to HU, the N remains essentially the same whereas the C increases. When the HU is removed, the N increases by 4× and the C continues to increase until just prior to recovery division when it also reaches a value 4× that of the original daughter cells. Thus, the N/C = 1 is re-established. The enlarged ECB formed during recovery division may function to lower the N/C in the daughter cells, which in turn may in some way stimulate immediate DNA replication, thus eliminating G₁. The elimination of G₁ (and shortening in a few subsequent cell cycles) allows less time for cytoplasmic growth and results in the return of the cells to the generation time and the N and C values observed prior to the HU treatment.     

CELL PROLIFERATION KINETICS OF EPIDERMIS AND SEBACEOUS GLANDS IN RELATION TO CHALONE ACTION

Median S-phase lengths of pinna epidermis and sebaceous glands, and of epithelia from the oesophagus and under surface of the tongue of Albino Swiss S mice were estimated by the percentage labelled mitoses method (PLM). The 18.4 and 18.8 hr for the median length of S-phase for pinna epidermis and sebaceous glands respectively made it possible for these two tissues to be used experimentally for testing tissue specificity in chalone assay experiments. The 10.0 and 11.5 hr for oesophagus and tongue epithelium respectively made experimental design for chalone assay difficult when pinna epidermis was the target tissue. The results of the Labelling Index measured each hour throughout a 24-hr period showed no distinct single peaked diurnal rhythm for pinna epidermis and sebaceous glands. Instead a circadian rhythm with several small peaks occurred which would be expected if an S-phase of approximately 18 hr was imposed on the diurnal rhythm. This indicates that there may be very little change in the rate of DNA synthesis. The results are given for the assay in vivo of purified epidermal G₁ and G₂ chalones, and the 72–81% ethanol precipitate of pig skin from which they could be isolated. These experiments were performed over a time period which took into account the diurnal rhythm of activity of the mice as well as the S-phase lengths. Extrapolating the results with time of action of the chalone shows that the G₁ chalone acts at the point of entry into DNA synthesis and that the S-phase length was approximately 17 hr for both the pinna epidermis and sebaceous glands. This may be a more correct value since the PLM method overestimates the median S-phase length as it is known that in pinna skin the [³H]TdR is available to the tissues for 2 hr and true flash labelling does not take place. The previous reports that epidermal G₁ chalone acts some hours prior to entry into S-phase resulted from experiments on back skin where the S-phase is shorter and there is a pronounceddiurnal rhythm which could mask the chalone effect. The epidermal G, chalone had no effect on DNA synthesis even at different times in the circadian rhythm. Thus the circadian rhythms and S-phase lengths of the test tissues need to be considered when experiments are performed with chalones. Ideally, the target tissues selected for cell line specificity tests should have the same cell kinetics for the easier and more accurate assessment and interpretation of results. When the tissues have markedly different cell kinetics, experimental procedures and results need to be evaluated accordingly. The point of action of G, chalone can only be assessed if the effect is measured over the peak of incorporation of 13H]TdR into DNA. The results of the effects of skin extracts are analysed in relation to changes in the availability of i3H]TdR for the incorporation into DNA and to the possibility of there being two distinct populations of proliferating cells.     

EXPERIMENTAL CONTROL OF DNA SYNTHESIZING AND DIVIDING CELLS IN EXCISED ROOT TIPS OF PISUM

The number of dividing and DNA-synthesizing cells in excised pea roots can be regulated by eliminating the carbohydrate normally supplied in the culture medium. When the excised roots were allowed to remain for 24 hr in a medium lacking carbohydrate, the number of mitotic figures and tritiated thymidine (H³-T) labeled cells was reduced almost to zero. After an additional 24 hr in the incomplete culture medium, 15% of the interphase cells were H³-T labeled, the percentage of the cells that were dividing never exceeded 1.4, and 30% of these were H³-T labeled. When the roots remained in the deficient medium for 72 hr, neither cell division nor cells synthesizing DNA were observed. Upon addition of 2% sucrose, cell division and DNA synthesis were resumed in the roots that were maintained for 24 or 72 hr without an exogenous carbohydrate supply. It has been hypothesized that some proliferative systems consist of two cellular subpopulations which selectively stop or remain in either the pre-DNA synthetic (G₁) or post-DNA synthetic (G₂) periods of the mitotic cycle. The addition of sucrose, H³-T, and 5-aminouracil to the medium, after the roots had been maintained for 24 hr without a carbohydrate, indicated that most of the proliferative cells in the roots had accumulated in either G₁, a quasi-G₁ condition, i.e., DNA synthesis stopped sometime before completion, or G₂ periods of interphase; the majority, however, were in G₁ or quasi-G₁ conditions. The results suggested that DNA synthesis (S period) and mitosis or the onset of these processes have the highest metabolic requirements in the mitotic cycle and that G₁ and G₂ were the most probable states for proliferative cells in a meristem with a low metabolic level.     

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.     

DNA synthesis and cell cycle progression of synchronized L-cells after irradiation in various phases of the cell cycle

Summary The varying sensitivity to radiation in the different phases of the cell cycle was investigated using L-929 cells of the mouse. The cells were synchronized by mechanical selection of mitotic cells. The synchronous populations were X-irradiated with a single dose of 10 Gy in the middle of the G₁-phase, at the G₁/S-transition or in the middle of the S-phase, respectively. The radiation effect was determined in 2 h intervals a) by¹⁴C-TdR incorporation (IT) into the DNA, b) by autoradiography (AR), c) by flow cytometry (FCM). The incorporation rate decreased in all three cases, but the reasons appeared to be different, as can be derived from FCM and AR data: After irradiation in G₁, a fraction of cells was prevented from entering S-phase, after irradiation at G₁/S a proportion of cells was blocked in the S-phase, and after irradiation in S, DNA synthesis rate was reduced. As a consequence of these effects, the mean transition time through S-phase increased. The G₂ blocks, obtained after irradiation at the three stages of the cycle were also different: Cells irradiated in G₁ are partly released from the block after 10 h. Irradiation at G₁/S caused a persisting accumulation of 50% of the cells in G₂, and for irradiation in S more than 80% of the cells were arrested in G₂.