Evidence for arrested G2 cell subpopulation in rat liver inducible to mitosis

The intraperitoneal administration of several substances (biliverdin, heat-killed bacteria and diatomaceous earth) to rats caused the prompt appearance of a mitotic wave in the liver. Autoradiographic analysis of livers of treated animals showed no evidence of [3H]-thymidine uptake by mitotic hepatocytes. In addition, livers from xenobiotic-treated rats showed a very low thymidine kinase activity, close to that found in normal livers. This excludes the possibility that non-cycling cells move to mitosis through the S phase. The results suggest that mitosis could be derived from a hepatocyte subpopulation arrested in the G2 phase of the cell cycle, which is stimulated to divide by the xenobiotics.     

Method For Probing Cells In Radiation-Induced G2Arrest: Demonstration of Potentially Lethal Damage Repair

Abstract. Chinese hamster ovary cells were arrested in the G₂ phase of the cell cycle by X-irradiation. When subsequently treated with 5 mM caffeine the arrested population progressed into mitosis as a synchronous cohort where it was harvested by mitotic cell selection. This procedure provides a means to isolate cell populations treated in G₂, for the investigation of G₂ arrest. Comparisons were made of the number of cells retrieved from G₂ arrest with the number suffering arrest, as determined by flow cytometry and by matrix algebraic simulations of irradiated cell progression. the retrieved population was not significantly less than expected for doses up to 3.5 Gy, indicating that the retrieval process does not favour the isolation of any population subset below this dose. Cell populations retrieved from arrest at varying intervals (0-3 h) after irradiation (0-3.5 Gy) showed an increase in survival with increase in interval, consistent with repair of potentially lethal damage. the repair curves (surviving fraction us time) were each described by a single exponential. G₂ cells that were brought to mitosis without a period of arrest exhibited the same radiation response as cells irradiated in mitosis.     

AUTORADIOGRAPHIC CONFIRMATION OF THE MITOTIC DIVISION OF EVERY MOUSE JEJUNAL CRYPT CELL LABELLED WITH 3H-THYMIDINE

The question was investigated of whether for crypt epithelia of the jejunum of the mouse all cells labelled after a single injection of ³H-TdR subsequently divide or whether cells exist in the crypt which synthesize metabolic DNA and, therefore, do not undergo division after labelling.
A double labelling experiment was performed with a first injection of ³H-TdR followed 1 hr later by an injection of ¹⁴C-TdR. Then from double emulsion autoradiographs of isolated squashed crypts the number of ³H-only, ¹⁴C-only and double labelled cells and mitoses were counted.
The double labelling produced a narrow, 1 hr wide sub-population of ³H-only labelled cells. This subpopulation of S cells completed its division before labelled cells were lost from the crypts by migration onto the villi. The results showed that this subpopulation of ³H-only cells completely doubled within 3 hr and then remained constant through 6 hr. From this result it was concluded that every cell labelled after a single injection of ³H-TdR divides.
From the same autoradiographs the flow rate through the end of mitosis was measured. From the flow rate and the mitotic index a mitotic duration of 0·5 hr was determined. The agreement of this measured mitotic time with the value calculated from the labelling index, mitotic index and S duration is also strong evidence that every labelled cell divides.
Both experiments show that the intestinal crypt does not contain cells synthesizing metabolic DNA.     

Turnover and Maturation Kinetics In the Hairless Mouse Epidermis. Continuous [3H]Tdr Labelling and Mathematical Model Analyses

Abstract. Hairless mice were continuously labelled with 10μCi of tritiated thymidine ([³H]TdR) every 4 h for 8 d, and the proportions of labelled basal and differentiating cells were recorded separately. the mitotic rate was measured by the stathmokinetic method and the cell cycle distributions were measured by flow cytometry of isolated basal cells at intervals during the labelling period. the mitotic rate of the [³H]TdR-injected animals did not deviate from control values during the first 5 d. Computer simulations of the data based on various mathematical models were made, and three main conclusions were obtained: (1) a large spread in transit times through the G₁ phase was found, together with a very narrow distribution in maturation time of differentiating cells; (2) about 20% of the differentiating cells were estimated to leave the basal cell layer directly after mitosis. This is consistent with results obtained from different sets of data; and (3) during continuous labelling more than 90% of the cells are labelled during each passage through the S phase.     

Cell cycle progression in human cells following re-oxygenation after extreme hypoxia: consequences concerning initiation of DNA synthesis

Abstract. The initiation of DNA synthesis and further cell cycle progression in cells during and following exposure to extremely hypoxic conditions in either G₁ or G₂+M has been studied in human NHIK 3025 cells. Populations of cells, synchronized by mitotic selection, were rendered extremely hypoxic (< 4 p.p.m. O₂) for up to 24n h. Cell cycle progression was studied from flow cytometric DNA recordings. No accumulation of DNA was found to take place during extreme hypoxia. Cells initially in G₁ at the onset of treatment did not enter S during up to 24 h exposure to extreme hypoxia, but started DNA synthesis in a highly synchronous manner within 1.5 to 2.25 h after reoxygenation. The duration of S phase was only slightly affected (increased by ≅10%) by the hypoxic treatment. This suggests that the DNA synthesizing machinery either remains intact during hypoxia or is rapidly restored after reoxygenation. Cells initially in G₂ at the onset of hypoxia were able to complete mitosis, but further cell cycle progression was blocked in the subsequent G^ Following reoxygenation, these cells progressed into S phase, but the initiation of DNA synthesis was delayed for a period corresponding to at least the duration of normal G₁ and did not appear in a synchronous manner. In fact, cell cycle variability was found to be increased rather than decreased as a result of exposure to hypoxia starting in G₂. We interpret these findings as an indication that important steps in the preparation for initiation of DNA synthesis take place before mitosis. Furthermore, the change in cell cycle duration induced by hypoxia commencing in G₁ is of a nature other than that induced by hypoxia commencing in other parts of the cell cycle.     

Arsenic trioxide suppresses paclitaxel-induced mitotic arrest

Objectives:  To understand if there exists a functional interaction between arsenic trioxide and paclitaxel in vitro.
Materials and methods:  HeLa and HCT116 ( ρ 53^+/+ and ρ 53^−/−) cells were treated with As2O3 and/or paclitaxel for various times. Treated cells were collected for analyses using a combination of flow cytometry, fluorescence microscopy and Western blotting.
Results:  Because As₂O₃ is capable of inhibiting tubulin polymerization and inducing mitotic arrest, we examined whether there existed any functional interaction between As₂O₃ and paclitaxel, a well-known microtubule poison. Flow cytometry and fluorescence microscopy revealed that although As₂O₃ alone caused a moderate level of mitotic arrest, it greatly attenuated paclitaxel-induced mitotic arrest in cells with p53 deficiency. Western blot analysis showed that As₂O₃ significantly blocked phosphorylation of BubR1, Cdc20, and Cdc27 in cells treated with paclitaxel, suggesting that arsenic compromised the activation of the spindle checkpoint. Our further studies revealed that the attenuation of paclitaxel-induced mitotic arrest by As₂O₃ resulted primarily from sluggish cell cycle progression at S phase but not enhanced mitotic exit.
Conclusion:  The observations that As₂O₃ has a negative impact on the cell cycle checkpoint activation by taxol should have significant clinical implications because the efficacy of taxol in the clinics is associated with its ability to induce mitotic arrest and subsequent mitotic catastrophe.     

A Changing Pattern of the Cell Cycle during the First Two Cleavage Divisions of the Mouse

The cell cycles of the early cleavage stages of the mouse were analyzed by examining Feulgen-stained ova. The period from ovulation to the completion of second cleavage division was investigated. The ova donors were C57BL/6 × DBA/2 female mice, which were hormonally superovulated. To estimate the durations of DNA synthesis and mitotic phases of the cleavage divisions, the ova were pooled into culture medium, and as a function of time, aliquots were removed from the batch of pooled ova. The ova specimens were Feulgen-stained and classified as the ova nuclei in G₁, S, G₂ or mitosis by use of a cytophotometric technique and then the durations of these phases were determined by probit analysis.
The pronuclear stage had a generation time of 11 hr, with a G₁ phase of 6 hr and a short S phase of 1.7 hr. In contrast the two-cell stage had a generation time of 18 hr, with a G₁ phase of 2 hr and an S phase of 3 hr. The duration of cleavage division also changed; the first cleavage division spanned 3 hr while the second spanned 1 hr.     

A comparative investigation of the antimitotic action of 2-mercaptoethanol and colcemid on V-79 Chinese hamster cells

Abstract. The current study was performed to characterize the antimitotic action of 2-mercaptoethanol (MET) on mammalian cells.
At concentrations of 2.5 × 10^-2 M, MET arrests V-79 Chinese hamster cells in metaphase. Smaller concentrations (from 5 × 10^-3 M) only produce a mitotic block after several hours, only arresting those mitoses which have gone through one cell cycle in the presence of MET. The accumulation of mitoses by MET is smaller in comparison with colcemid, explained by an effect reducing the number of cells which enter mitosis. In contrast to colcemid, MET-concentrations which do not lead to a mitotic block cause a delay in proliferation. It was shown, by means of the BUdR-labelling method that cells in the presence of colcemid concentrations which arrest mitosis again enter interphase and become polyploid, whereas MET leads to an irreversible arrest of mitosis and does not produce polyploidy in V-79 cells.     

INFLUENCE OF METABOLIC DNA ON DETERMINATIONS OF THE CELL CYCLE

Abstract. Evidence in favour of labelling of DNA in excess of requirements for mitosis was found in adult organs showing no mitosis (heart muscle and brain), in organs with low mitotic indexes (liver, seminal vesicle) and, more recently, in the small intestine of rodents, in bone formation and in growing roots of Vicia faba. A survey of published data showed higher labelling indexes than would be expected from the data for S, M and t _c deducted from labelled mitoses curves. to improve the accuracy of the data needed for a complete assessment the duration of mitosis (M) and the proportion of cells which are no longer in the mitotic cycle in the crypts were determined using Colcemid. the fact that all cells in the villi are derived from the crypts and that there is no cell-loss in the villi was checked by cell-counts.
The results show that 3040%of the labelled nuclei found in crypts of the jejunum of mice at 1 hr after injection of ³H-thymidine do not proceed to mitosis.
The labelling after the last mitosis is interpreted as formation of the metabolic DNA necessary for the function of the differentiated cells in the villi. There is some evidence that metabolic DNA necessary for the processes of mitosis might be lost     

Age-related changes in the cell kinetics of rat foot epidermis

Abstract. The durations of the cell cycle and its component phases have been determined for the basal layer of the epidermis of the skin from the upper surface of the hind foot of the rat using single pulse [³H]-thymidine labelling and the percent labelled mitosis (PLM) technique. Rats of three age groups were used, namely 7, 14 and 52 weeks. The duration of DNA synthesis (T_s) and the G₂ plus M phase (Tg₂± m) were comparable in 7-week and 52-week-old rats ( P > 0–1). The major difference between 7-week and 52-week-old rats was in the duration of the G₁ phase (Tg₁). In 7-week-old rats Tg₁ was 15.0 ± 0.8 h and in 52-week-old rats Tg₁ was 31.2 ± 3.5 h. A consequence of this variation was that the overall duration of the cell cycle was longer in 52-week-old rats (53.9 ± 5.3 h) than in 7-week-old rats (30.1 ± 1.3 h).
Difficulties were found in fitting a simple curve to the PLM data for 14-week-old rats. This suggests that the proliferative cell population of the epidermis of rats of this age group may be heterogeneous. A satisfactory fit to the data was obtained using a computer model which assumed that the proliferative population of the epidermis of 14-week-old rats was a mixture of cells with cell cycle parameters the same as those of the 7-week and the 52-week-old rats. These two sub-populations of relatively slowly and rapidly proliferating cells were present in the ratio of 2:1.     

Monocytic differentiation of HL60 cells induced by potent analogs of vitamin D3 precedes the G1/G0 phase cell cycle block

Abstract. Differentiation of mammalian cells is accompanied by reduced rates of proliferation and an exit from the cell cycle. Human leukemic cells HL60 present a widely used model of neoplastic cell differentiation, and acquire the monocytic phenotype when exposed to analogs of vitamin D₃ (VD₃). The maturation process is accompanied by two blocks in the cell cycle: an arrest in the G₁/G₀ phase, and a recently described G₂+ M block. In this study we have analyzed the traverse of the cell cycle phases of the well-differentiating HL60-G cells exposed to one of ten analogs of VD₃, and compared the cell cycle effects of each compound with its potency as a differentiation-inducing agent. We found that in general there was a good correlation between the effects of these compounds on the cell cycle and on differentiation, but the best cell cycle predictor of differentiation potency was the extent of accumulation of the cells in the G₂ compartment. All analogs induced a marked decrease in the mitotic index, and polynucleation of HL60 cells was produced, especially by compounds which were effective as inducers of differentiation. Time course studies showed that induction of differentiation was accompanied by a transient increase of the proportion of cells in the G₂+ M compartment, but preceded the G₁ to S, and the G₂ compartment blocks. These studies indicate that complex changes in the cell cycle traverse accompany, but do not precede, the acquisition of the monocytic phenotype by HL60 cells.     

REGULATION AND KINETICS OF SPERMATOGONIAL PROLIFERATION IN ARENICOLA MARINA (ANNELIDA, POLYCHAETA) II. KINETICS

The rate of accumulation of mitoses in the testis of Arenicola marina has been estimated by the colchicine method. The rate is low in February but increases during spring to a maximum in June. The rate remains high during July and August but decreases in September. A second temporary and minor rise was observed in October or November prior to spawning.
The rate of accumulation of mitoses (with respect to the duration of metaphase arrest) is logarithmic from February to June, but is arithmetic during the latter part of the reproductive cycle (July-October). The transition from one phase to the next coincides with the initiation of spermatocyte release from the testis into the coelom.
The rate of accumulation of mitoses has also been recorded in testes cultured in vitro. The rate in vitro does not differ from that in vivo in May when the rate is high, but in September when the rate in vivo is depressed, culture in vitro significantly increases the mitotic rate.
The cell cycle time of the proliferating spermatogonia has been estimated by a modified per cent labelled mitosis technique. The cell cycle time is unusually long (in excess of 20 days) and the G₂ period is at least 5 days. It is suggested that the testis of A. marina is an exponentially growing cell population from February until early June when coelomic spermatocytes first appear. The rate of cell release then temporarily exceeds the rate of renewal: eventually they become equal and the testis remains in steady state until September when the mitotic rate is depressed due to the presence of maturing spermatocytes. The depression of the mitotic rate in September is achieved by the arrest of spermatogonia in G₂. Explanting the gonads in organ culture removes the inhibition and causes an increased flow of cells from G₂ into mitosis.     

Effect of separase depletion on ionizing radiation-induced cell cycle checkpoints and survival in human lung cancer cell lines

Abstract.   Objectives : This study is to evaluate the effect of separase depletion on cell cycle progression of irradiated and non-irradiated cells through the G₂/M phases and consecutive cell survival. Materials and methods : Separase was depleted with siRNA in two human non-small cell lung carcinoma (NSCLC) cell lines. Cell cycle progression, mitotic fraction, DNA repair, apoptotic and clonogenic cell death were determined. Results : By depletion of endogenous separase with siRNA in NSCLCs, we showed that separase affects progression through the G₂ phase. In non-irradiated exponentially growing cells, separase depletion led to an increased G₂ accumulation from 17.2% to 29.1% in H460 and from 15.7% to 30.9% in A549 cells and a decrease in mitotic cells. Depletion of separase significantly ( P <  0.01) increased the fraction of radiation-induced G₂ arrested cells 30–56 h after irradiation and led to decrease in the mitotic fraction. This was associated with increased double-strand break repair as measured by γ-H2AX foci kinetics in H460 cells and to a lesser extent in A549 cells. In addition, a decrease in the expression of mitotic linked cell death after irradiation was found. Conclusions : These results indicate that separase has additional targets involved in regulation of G₂ to M progression after DNA damage. Prolonged G₂ phase arrest in the absence of separase has consequences on repair of damaged DNA and cell death.     

Heterogeneity in the mouse epidermal cell cycle analysed by computer simulations

Abstract. Different sets of cell kinetic data obtained over many years from hairless mouse epidermis have been simulated by a mathematical model including circadian variations. Simulating several independent sets of data with the same mathematical model strengthens the validity of the results obtained. The data simulated in this investigation were all obtained with the experimental system in a state of natural synchrony. The data include cell cycle phase distributions measured by DNA flow cytometry of isolated epidermal basal cells, fractions of tritiated thymidine ([³H]TdR) labelled cells within the cell cycle phases measured by cell sorting at intervals after [³H]TdR pulse labelling, bivariate bromodeoxyuridine (BrdUrd)/DNA data from epidermal basal cells isolated at intervals after pulse labelling with BrdUrd, mitotic rate and per cent labelled mitosis (PLM) data from histologic sections. The following main new findings were made from the simulations: the second PLM peak observed at about 35 h after pulse labelling is hardly influenced by circadian variations; the peak is mainly determined by persisting synchrony of a rapidly cycling population with a G₁-duration (T_G1) of 20 h to 30 h; and there is a highly significant population of slowly cycling G₁-cells (G_1σ). However, no significant circadian variations were found in the number of these cells.     

Cytogenetic analysis of Australian tiger beetles (Coleoptera: Cicindelidae): chromosome number, sex-determining system and localization of rDNA genes

The chromosomes of four species of Australian tiger beetle are documented. The male meioformulae of three species of Cicindela (tribe Cicindelini) were determined as follow: Cicindela cardinalba Sumlin 1987, n = 10 + X₁ X₂ X₃Y; C. sp. ( saetigera group) and Cicindela gillesensis Hudson 1994, n = 11 + X₁ X₂ X₃Y. The male meioformula of Megacephala whelani Sumlin 1992 (tribe Megacephalini) is n = 12 + XY. Fluorescence in situ hybridization (FISH) was used to localize the 18S-28S ribosomal gene clusters on male mitotic and meiotic chromosomes and nuclei using a polymerase chain reaction-amplified ribosomal probe. Fluorescence in mitosis and meiotic first prophase stages in the three Cicindela species showed that rDNA genes are in two of the four chromosomes that form the sex vesicle. In M. whelani hybridization in mitosis and first metaphase stages indicate that rDNA genes are in three, medium- to small-sized, autosomal pairs. Silver staining of male meiotic nuclei reveals the presence of active nucleolar organizing regions (NORs) in the sex vesicle of the three species of Cicindela . The cytogenetic and evolutionary implications of these findings are discussed.     

cAMP IN THE CELL CYCLE OF THE DINOFLAGELLATE CRYPTHECODINIUM COHNII (DINOPHYTA)

The second messenger cAMP is a key regulator of growth in many cells. Previous studies showed that cAMP could reverse the growth inhibition of indoleamines in the dinoflagellate Crypthecodinium cohnii Biecheler. In the present study, we measured the level of intracellular cAMP during the cell cycle of C. cohnii . cAMP peaked during the G₁ phase and decreased to a minimum during S phase. Similarly, cAMP-dependent protein kinase activities peaked at both G₁ and G₂+M phases of the cell cycle, decreasing to a minimum at S phase. Addition of N6, O₂'-dibutyryl (Bt₂)-cAMP directly stimulated the growth of C. cohnii . Flow cytometric analysis of synchronized C. cohnii cells suggested that 1 mM cAMP shortened the cell cycle, probably at the exit from mitosis. The size of Bt₂-cAMP treated cells at G₁ was also larger than the control cells. The present study demonstrated a regulatory role of cAMP in the cell cycle progression in dinoflagellates.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

Abstract. The kinetics of isthmal cells in mouse antrum were examined in three ways: (a) the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; (b) the duration of interphase and mitotic phases was determined from how frequently they occurred; and (c) mice were killed at various intervals after an intravenous injection of ³H-thymidine to time the acquisition of label by the various phases of mitosis.
The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G₁ and G₂ stages were 6.8 and 1.0 hr, respectively.
From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr.
Ten minutes after an intravenous injection of ³H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase.
We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G₂. Also, nuclei are in telophase during the early half of G₁ but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G₁ into early and late periods is practical.     

A Factor That Interrupts the Cell Cycle at G2 or Prophase is Present in Full-Grown Frog Oocytes

Full-grown amphibian oocytes that had been arrested at meiotic prophase I contained an activity that prevented the cell cycle from progressing beyond a G₂-like stage. Injection of the contents of germinal vesicles (GV-content) or cytoplasm obtained from oocytes of the frog Rana rugosa prevented fertilized eggs of Cynops pyrrhogaster or Bufo japonicus from cleaving. The nuclei in the arrested eggs consisted of thin chromosomes and nucleolus-like particles enclosed within clear nuclear membrane and their volume increased as a function of time after injection. Cycling of maturation-promoting factor (MPF) did not occur in the injected eggs, but DNA synthesis was not disturbed. The injection of exogenous MPF into the eggs induced the reinitiation of the cell cycle with progression to the M phase and subsequent cleavage. Furthermore, the injection into the full-grown oocytes of Bufo inhibited induction of the maturation of oocytes by progesterone. These results demonstrate that a factor that arrests the cell cycle either at a G₂-like stage of mitosis or at prophase in meiosis is present both in the GV and cytoplasm of frog oocytes. We refer to this factor as a G₂-specific cytostatic factor (G₂-CSF). G₂-CSF may play an important role not only in the physiological arrest at prophase I in meiosis, but also in regulation of the G₂/M transition in the cell cycle of early embryonic cells.     

Phosphorylation of Cdc20/fizzy negatively regulates the mammalian cyclosome/APC in the mitotic checkpoint

The cyclosome/anaphase promoting complex (APC) is a multisubunit ubiquitin ligase that targets mitotic regulators for degradation in exit from mitosis. It is activated at the end of mitosis by phosphorylation and association with the WD-40 protein Cdc20/Fizzy and is then kept active in the G1 phase by association with Cdh1/Hct1. The mitotic checkpoint system that keeps cells with defective spindles from leaving mitosis interacts with Cdc20 and prevents its stimulatory action on the cyclosome. The activity of Cdh1 is negatively regulated by phosphorylation, while the abundance of Cdc20 is cell cycle regulated, with a peak in M-phase. Cdc20 is also phosphorylated in G2/M and in mitotically arrested cells, but the role of phosphorylation remained unknown. Here we show that phosphorylation of Cdc20 by Cdk1/cyclin B abrogates its ability to activate cyclosome/APC from mitotic HeLa cells. A nonphosphorylatable derivative of Cdc20 stimulates cyclin-ubiquitin ligation in extracts from nocodazole-arrested cells to a much greater extent than does wild-type Cdc20. It is suggested that inhibitory phosphorylation of Cdc20/Fizzy may have a role in keeping the cyclosome inactive in early mitosis and under conditions of mitotic checkpoint arrest.     

Circadian synchronization of hepatocyte proliferation in young rats: the role played by adrenal hormones

Abstract. From the 20th day to the 30th day of life, the mitotic rhythm is progressively induced by a reduction in nocturnal values, while diurnal rhythms remain unchanged. Mitotic peaks emerge at 10.00 hours.
A labelling index wave occurs 8 hr before the corresponding mitotic wave, with a peak at 02.00 hours and a minimum in the evening, coincidental with the acrophase of plasma corticosterone level (activity phase).
Labelled mitoses curves and metaphase accumulation after colchicin injection show that the duration of the S, G₂ and M phases remain approximately constant and that the circadian variation is due to a variation in the rate of cells that enter these successive phases. During the synchronization period (from day 20 to 30), the growth fraction decreases progressively. Adrenalectomy at this time is followed by a higher cell proliferation and all rhythms disappear after 2 days.
Corticosterone injected before the triggering of the rhythmic activity in 17-day-old rats immediately reduces the labelling index, while the mitotic index is decreased 10 hr later; this delay is equal to the S + G₂ duration.
The results are discussed. They favour the hypothesis that the circadian variation of corticosterone is responsible for the induction of a circadian variation in developmental cell proliferation by inhibition of the G₁-S transition when it is higher in the evening.
The circadian rhythm of hepatic cell proliferation in rats appears on the 20th day of life, when the hypothalamo-adrenal axis is mature enough for circadian activity to occur.