Effect of graft versus host reaction on cell cycle time in neonatal mouse jejunum

The duration of cell cycle parameters in control mouse jejunum has been compared with that found following induction of a graft-versus-host reaction (GvHR) during the first 3 weeks of postnatal life. Values for tc and tG1 were found to decrease progressively during normal development: estimates for the whole crypt column in 21-day-old mice were approximately half to one quarter those found 6 days after birth 12.1 +/- 0.5 hr and 24.2 +/- 0.3 hr for tc; 2.8 +/- 0.3 hr and 12.1 +/- 0.3 hr for tG1 respectively; (means +/- SE). tS and tG2 were found to remain approximately constant during this period of neonatal development. Injecting foreign spleen cells into 3-day-old mice produced no effect on crypt cell proliferation or cell cycle parameters measured 3 days later. GvHR mice studied 8 days after spleen cell injection, however, showed both an increase in crypt cell proliferation and decreases in the values for tc and tG1 to levels similar to those normally found in 21-day-old control animals (tc 12.4 +/- 0.4 hr and tG1 5.4 +/- 0.4 hr for 11-day-old GvHR mice). The possible mechanism leading to these changes is discussed. The ability of GvHR to stimulate cell proliferation is used in the present work to test the hypothesis that the total number of cell divisions taking place after birth determines the temporal sequence of changes in disaccharidase content produced during neonatal development.     

Cell population kinetics in pig epidermis: further studies

Abstract. The cell population kinetics of the epidermis were studied in 4-month-old pigs. Mitotic figures were confined to the basal cell (L1) and the first suprabasal cell layer (L2). The mitotic index (MI) was 0.17 ± 0.04% for L1 and 0.08 ± 0.03% for L2. Labelled nuclei were distributed throughout the viable epidermis, the majority (79.1 ± 1.1%) were in L1 with 19.5 ± 1.2% in L2. The labelling indices (LI) in layers L1 and L2 were 7.1 ± 0.4% and 3.4 ± 0.1%, respectively. After labelling with two injections of tritiated thymidine [³H]TdR separated by 90 min, the LI increased to 8.2 ± 0.3% in L1 and to 4.0 ± 0.2% in L2. This increased labelling confirmed that cell proliferation occurs in both layers, L1 and L2, of the epidermis.
The cell production rate ( K ) in L1 and L2 had an upper limit of 10.7 ± 1.0 and 6.2 + 1.8 cells per 1000 cells per hour respectively. The cell flow rate per hour (cell flux), into and out of the DNA synthesis phase (S), and the duration of DNA synthesis were determined from double-labelling studies with [³H]TdR and [¹⁴C]TdR. The cell flux into and out of S was identical and was calculated as 0.6 ± 0.1%/hr (L1) and 0.5 ± 0.1%/hr (L2). Values for t _S varied from 8 to 10 hr. The cell turnover times ( t _T) were in the range 89–129 hr and 180–261 hr for L1 and L2, respectively.
Log normal curves were fitted to the fraction labelled mitoses data for L1 and L2. Values for t _S for cells in L1 and L2 were 9.8 hr and 11.9 hr, respectively. t _G2+ 1/2 t _M was 7.2 hr in L1 and 9.1 hr in L2.     

DNA SYNTHESIS TIME IN LEUKAEMIC CELLS AS MEASURED BY THE DOUBLE LABELLING AND THE PERCENTAGE LABELLED MITOSES METHODS

Values of T _s provided by the double labelling method have been compared with those given by the percentage labelled mitoses curve for blast cells in the peripheral blood of a patient with plasma cell leukaemia and of rats bearing a transferable acute leukaemia. the double labelling method was carried out giving the first label (³H-thymidine) in vivo and the second label (¹⁴C-thymidine) in vitro with several values for the interval between the two labels. T _s was calculated by fitting regression lines to the results obtained. Data for percentage labelled mitoses were analysed by computer. For the plasma cell leukaemia values of T _s= 17.1 ± 7.0 hr and T _s= 19.8 ± 3.4 hr, and for the rat leukaemia values of 8.7 ± 1.7 hr and 9.0 ± 1.7 hr (7.1 hr corrected for exponential growth) were obtained from the percentage labelled mitoses and double labelling methods respectively. It is concluded that the double labelling method is valid for the study of cell proliferation in leukaemic blast cells.     

KINETICS OF GROWTH OF HAEMOPOIETIC COLONY CELLS IN AGAR

Cell kinetic parameters of mouse granulocytic and mononuclear cells growing in colonies in agar cultures have been measured. Analysis of flash and continuous labelling studies with ³H-thymidine together with determinations of colony size, growth fraction and mitotic indices, gave the following values for the phases of the cell cycle: G₁= 6·3 1·6 hr, S = 5·8 ± 1·4 hr, G₂= 1·7 ± 0·1 hr and M = 0·7 ± 0·1 hr (42 ± 8 min). No difference in the cell cycle parameters of granulocytic and mononuclear cells were found in this study.
Colonies of different size from cultures of the same age group had similar labelling indices, indicating that the size of a colony is not a function of the rate of proliferation of cells in the colony. Rather, variation in colony size is probably representative of an initial delay in the onset of colony development.     

Growth pattern of the human promyelocytic leukaemia cell line HL60

Abstract. In order to characterize the growth pattern of the human promyelocytic leukaemia cell line HL60, its kinetic parameters were studied. The doubling time was calculated from serial cell counts, the duration of the various cell cycle phases from the analysis of the labelled mitoses curve, and quiescent population from continuous labelling experiments. Proliferation in culture was exponential up to a saturation density of about 3.0 × 10⁶ cells/ml, with a doubling time of 34.0 hr. The cell cycle duration was 24.3 ± 4.1 hr (SD), and that of the cell cycle phases was: G₁, 3.8 ± 2.2 hr; S, 15.1 ± 3 hr; and G₂, 5.4 ± 1.2 hr. The growth fraction was 0.85, and cell loss was restricted to the quiescent cells. The HL60 cell line, with fully characterized kinetics, provides a useful tool for the in vitro study of substances which may affect human leukaemic myelopoietic proliferation.     

CARTILAGE CELL PROLIFERATION IN THE TAIL-VERTEBRAE of NEW-BORN RATS

Cartilage cell proliferation has been studied in the tail-vertebrae of new-born rats. At 1 day the median cycle time for cartilage cells was about 22 hr; G¹+ 1/2M, S, and G²+ 1/2M being 6.8 ± 2.5, 11.6 ± 2.2, and 4.6 ± 2.0 hr respectively. At 7-10 days, cell proliferation is confined mainly to the lower half of the epiphysis. Here cycle times are longer, about 3 1/2 days in the most active region. Differences in cycle times appear to be due to either a lengthening of G¹ or the entry of cells into a resting state. Changes in cartilage cell kinetics are discussed in relation to the structure and function of the epiphysis.     

CELL POPULATION KINETICS OF PLUCKED AND UNPLUCKED MOUSE SKIN I. UNIRRADIATED SKIN

A detailed study of the cellular proliferation kinetics in interfollicular plucked and unplucked mouse skin has been made in Swiss albino mice, using tritiated thymidine autoradiography. Diurnal variations in mitotic and labelling indices were demonstrated in both systems.
The mean cell cycle times for unplucked and plucked skin were estimated by four different methods and found to be 100 ± 10 and 47 ± 3 hr respectively. Most of the difference was due to the shortening of G₁ phase after plucking. Repeated labelling at intervals shorter than the DNA synthesis times resulted in all the basal layer cells becoming labelled, so that the growth fraction was unity, in unplucked and plucked skin.
A well-defined second wave of labelled mitoses was seen at about 100 hr after labelling the unplucked (i.e. normal) mouse skin.
A double labelling technique using ¹⁴C-TdR and ³H-TdR with a single layer of emulsion gave reasonable values for the duration of the DNA synthesis phase.     

Acinar cell proliferation in the parotid and submandibular salivary glands of the neonatal rat

Abstract. Although the rat salivary glands are deficient in acini at birth, acinar cells proliferate rapidly during the early post-natal period. The pattern of acinar cell proliferation was analysed in the parotid and submandibular glands of neonatal rats from day of birth until day 34. Mitotic and [³H]thymidine ([³H]TdR) labelling indices of the two glands show distinctly different patterns. Analysis of cell division in the rat parotid gland demonstrated a peak of mitotic index at 14 days (2.9 ± 0.4%) and labelling index at 16 days (25.2 ± 2.1%). Submandibular gland acinar cell proliferation reaches a zenith between 7–8 days; labelling index (14.2 ± 1.1%) and mitotic index (2.3 ± 0.3%). Cell proliferation decreases rapidly in both glands after reaching a peak in activity. Gland size increases more rapidly in the submandibular gland which correlates with the earlier shift from cell proliferation to differentiation which occurs in this organ. Circadian rhythms of [³H]TdR incorporation were also investigated in this study. A circadian rhythm of [³H]TdR incorporation into DNA occurs at 15 days after birth with a peak at 06.00 hours in both glands and a trough occurring at 15.00 hours in parotid gland and 18.00 hours in the submandibular gland. Determination of specific activity of DNA (ct/min per μg DNA) on days 8, 10, 12, 13, 14, 15, and 16 after birth at 06.00 and 15.00 hours indicated that a circadian rhythm in [³H]TdR incorporation into DNA began on day 14. The developmental switch from suckling to solid food may be an initiating factor in the sychronization of the circadian rhythm in cell proliferation.     

Proliferation kinetics of plasma cells and of normal haemopoietic cells in multiple myeloma

Abstract. DNA synthesis time ( T _s) and ³H thymidine (TdR) labelling index (LI) of bone marrow (BM) myelomatous plasma cells (PC) and of the residual haemopoietic cell population (RHCP) were measured by in vitro quantitative ¹⁴C-TdR autoradiography in five patients with multiple myeloma (MM) in different phases of disease (three at presentation and two at relapse) and in one patient with solitary extra-osseous myeloma. One other patient with plasma cell leukaemia (PCL) was studied during an initial relapse phase and later during the leukaemic terminal phase. PC T _s was 18.8 ± 3.7 (from 13.3 to 25.0) hr and PC LI was 2.5 ± 1.8%; (from 1.0 to 6.3%). In the case of PCL, circulating PC had a T _s of 14.4 hr and a LI of 3.1. From these experimental measurements, the fractional turnover rate (FTR—percentage of cells produced per unit time) and the potential doubling time ( T _d) of BMPC were calculated assuming that all BMPC were in a steady-state at the time of the study. BMPC FTR was 3.53 ± 2.3% cells per day (from 1.2 to 6.72) and BMPC T _d was 46.8 ± 27.5 days (from 15.0 to 75.4). Comparison with results obtained in BM blasts of children with acute lymphoblastic leukaemia (ALL) indicated that BMPC had a lower proliferative activity ( P < 0.001), although BMPC T _s was not significantly different. In two patients a tumour doubling time of 6 and 13 months was determined by clinical follow up. Comparison of this parameter with T _d showed a cell loss factor of more than 90% in both patients.
Kinetic data relative to RHCP showed slight variations with respect to those found in normal subjects, with a general tendency towards a prolongation of T _s and a reduction of LI.     

Acute lethal graft-versus-host disease stimulates cellular proliferation in the adult rat liver

Abstract. The present investigation was designed to analyse the effects of acute lethal graft-versus-host disease (GVHD) in adult (DA x LEW)F₁ rats on cellular proliferation within the liver. The influence of the host thymus on GVHD-induced proliferation was also assessed. From 1–28 days after initiation of GVHD [³H]thymidine ([³H]-TdR) was injected i.v. and rats were killed one hour later. Percentage labelled cells (LI) of periportal infiltrating cells (PIC), hepatocytes (H), and sinusoidal lining cells (SC) were counted. Mean values for control rats were 0.3 ± 0.1% (H), 0.4 ± 0.1% (SC) and 0.2 ± 0.1% (PIC). GVHD rats demonstrated a significant increase in LI of PIC (days 1–21), SC (days 2–17) and H (days 2–17). Most labelled cells in PIC were large lymphocytes. Peak LI values were 7.0 ± 1.0% PIC (day 17), 6.8 ± 0.9% SC (day 17), and 5.2 ± 0.9% H (day 7), with all cellular compartments returning to near normal LI values by day 28. Stimulation of cellular proliferation occurred in all three liver cell compartments in neonatally thymectomized (TXM) rats. The intensity of GVHD-induced cell proliferation was significantly decreased at day 7 in all compartments and PIC was dramatically decreased at day 21 in TXM-GVHD rats as compared to non-TXM-GVHD rats. It is hypothesized that the general stimulation of hepatocyte cell proliferation in GVHD is related to the secretion of lymphokines by primarily donor and secondarily host T cells in the periportal infiltrate.     

DOUBLE PULSE LABELLING WITH 3H-THYMIDINE: A METHOD FOR CALCULATING CELL POPULATIO KINETICS

A method was developed for calculating cell population kinetics with the aid of double pulse labelling with ³H-TdR. The labelling index was measured from auto-radiographs of the oral epithelium of two groups of 30-day-old rats. One group was injected once with ³H-TdR the other twice, with a time interval of 90 min between injections. DNA synthesis time was calculated from the equation:
   
where T _s= synthesis time; LI₁= labelling index in the single-injected group; LI₂= labelling index in the double-injected group; and T _i= time interval between injections. Synthesis time in the palate was 4.8 hr and 7.6 hr in the tongue. Generation time was calculated from the equation: T _g= ( T _s/LI₁) × 100, where T _g= generation time. Generation time in the palate was 46.1 hr and 75.8 hr in the tongue     

THE KINETICS OF GRANULOSA CELLS IN DEVELOPING FOLLICLES IN THE MOUSE OVARY

This investigation describes the kinetics of the granulosa cells in medium-sized follicles type 3b, 4 and 5a in ovaries of 28-day-old Bagg mice. the method of labelling with ³H-thymidine followed by high resolution autoradiography is used in the experimental work, which consist of determining percentage labelled mitosis (PLM-) and continuous labelling (CL-) curves. In order to analyse the data by computer two alternative hypotheses A and B are set up. Both include the assumptions of no cell loss, exponential growth and a resting compartment Q. In hypothesis A cells from Q re-enter the mitotic cycle via the normal DNA-synthesis compartment S_p. Hypothesis B includes beside compartment S_p a special DNA-synthesis compartment S_q where only cells from Q are synthesizing DNA, and these cells re-enter the mitotic cycle via the G₂ compartment. the mean transit time in S_q is considered to be longer than the mean transit time in S_q. On the basis of the hypothesis mathematical expressions for the PLM- and CL-curves are obtained, and by means of a computer the theoretical curves are fitted to the experimental values: thereby all relevant cell kinetical parameters are estimated. Hypothesis B seems to give the best fit between the theoretical and experimental curves. the estimated parameters are: mean cycle times, μ_c= (56.1 hr, 56.1 hr and 22.3 hr for type 3b, 4 and 5a respectively), doubling times, T _D= (96.4 hr, 118.6 hr and 59.1 hr) and the proportion of cells in Q, p _Q = (0.60, 0.71 and 0.69).     

Modulation of F1 cytotoxic potentials by GvHR. Host- and donor-derived cytotoxic lymphocytes arise in the unirradiated F1 host spleens under the condition of GvHR-associated immunosuppression

As an approach to dissect complex cellular events that lead to GvHR-associated immune disorders, we followed cytotoxic activities, including NK cytotoxicity, in the spleens of unirradiated F1 hosts undergoing GvHR induced by parental spleen cells. Spleen cells of (B10 X DBA/2)F1 or (B10 X AKR/J)F1 hosts undergoing GvHR induced by parental B10 spleen cells displayed a prompt and marked increase in NK cell activity within 36 hr, and the heightened activity lasted until day 8. The activity then declined abruptly and disappeared on day 12 of GvHR. Inversely, donor B10-derived CTL specifically directed to the opposite parental alloantigens of the F1 hosts emerged in these F1 host spleens on day 8, and the CTL activity reached a peak on day 12 when the host NK cell activity disappeared. During the period that the donor-derived anti-host CTL were present, these F1 host spleen cells lost not only NK cell activity but also the ability to mount in vitro CTL responses. In contrast, the respective F1 strain mice undergoing GvHR induced by the parental DBA/2 or AKR/J spleen cells showed only transient but marked increases in NK cell activity during the initial 36 hr, and then the activity decreased gradually to return to the normal level on day 10. In such GvHR F1 host spleens, donor-derived CTL could never be detected, and the spleen cells showed normal in vitro CTL responsiveness during the entire observation period of 16 days. These results are discussed from the viewpoint of genetically defined cellular events that lead to the GvHR-associated immune disorders.     

VARIATION IN THE DURATION OF MITOSIS IN THE CRYPTS OF LIEBERKUHN OF THE RAT; A CYTOKINETIC STUDY USING VINCRISTINE

The variation in the duration of mitosis ( t _m) with cell position in the small intestinal crypts of the adult rat has been measured by a stathmokinetic technique using vincristine. The value for the whole crypt column was 0.43 hr, or 26 min. At the bottom of the crypt t _m was in excess of 1 hr, but rapidly decreased and throughout the greater part of the proliferative compartment was between 0.40 and 0.50 hr. At the top of the proliferative compartment an increase in t _m was demonstrated.
If the value of 0.43 hr for the whole crypt column is correct, then one argument for postulating the formation of metabolic DNA during differentiation in the small bowel epithelium of the rat becomes invalid. Variations in t _m within the crypt have been shown to increase the values of cell velocity obtained from cumulative birth rate diagrams. Finally further evidence has been presented for the existence of a slowly dividing subpopulation of cells at the base of the crypt. These cells may be important in crypt repopulation after damage with phase specific anti-tumour drugs.     

Intestinal Cell Proliferation. I. A Comprehensive Model of Steady-State Proliferation In the Crypt

Abstract. Cell replacement in the crypt of the murine small intestine has been studied and modelled mathematically under steady-state conditions. A great deal of information is available for this system, e.g. cell cycle times, S phase durations, the rate of daily cell production, the Paneth cell distribution etc. the purpose of the present work was to consider simultaneously as much of these data as possible and to formulate a model based upon the behaviour of individual cells which adequately accounted for them. A simple mathematical representation of the crypt has been developed. This consists of sixteen stem cells per crypt (T_c= 16 hr, T_s= 9 hr), and four subsequent transit cell divisions (T_c= 11 to 12 hr, T_s= 8 hr) before maturation. Experimental data considered to test the modelling were LI and data on the number of vertical runs of similarly labelled cells. All data were obtained from the ileum after 25 μCi [³H]TdR given at 09.00 hours. A number of alternative assumptions have been considered and either accepted or rejected. Two alternative model concepts of cell displacement explain the data equally well. One is dependent upon strong local cell generation age determinance while the other could accommodate any weak local cell displacement process in conjunction with an environmental cut-off determinant at the middle of the crypt. Both models provide new interpretations of the data, e.g. certain rates of lateral cell exchange between neighbouring columns (250 to 350 per crypt per day out of a total of 420 cell divisions per day) can be concluded from run data, while LI data provide information about the mechanisms involved in maintaining a position-related age order in the crypt.     

CELL CYCLE PROPERTIES OF DIFFERENTIATING SPERMATOGONIA IN ADULT SPRAGUE-DAWLEY RATS

The duration of the mitotic cycle and of its components was analysed for each of the six successive generations of differentiating spermatogonia (A₁, A₂, A₃, A4, intermediate and B), using radioautographed whole mounts of seminiferous tubules from testes of adult Sprague-Dawley rats. Cell cycles were determined from two successive waves of per cent labeled metaphases obtained during the period of 81 hr after a single dose of ³H-thymidine. Except for the A₁ spermatogonia, all spermatogonial types (A₂ to B) had similar cell cycle durations of 41-42.5 hr and comparable pre-DNA synthesis phases (G₁) of 11-13 hr. Although the combined duration of DNA synthesis (S) and the post-synthesis phase (G₂) remained identical for all the cell types including A₁, there was a progressive lengthening of the S period at the expense of G₂ during the process of spermatogonial maturation. This change was most marked during the transition from A₁ to A₃ spermatogonia when the S period increased from 14 hr to 21 hr, and the G₂ phase shortened from 13 hr to 7.5 hr. This feature seems to be unique to germ cells and may be associated with an increasing amount of heterochromatin in the nucleus. Excluding the development of type A₁ cells, the entire process of spermatogonial maturation lasted for 208 hr. Combined data on cell cycle times indicated that every 313 hr or 13 days, a new sequence of spermatogonial differentiation was initiated by the A₁ cells. This was equivalent to the duration of one 'cycle' of the seminiferous epithelium as measured by other techniques.     

Exogenous bone marrow cells do not rescue non-irradiated mice from acute renal tubular damage caused by HgCl2, despite establishment of chimaerism and cell proliferation in bone marrow and spleen

Abstract.   Objective : Various studies have shown that bone marrow stem cells can rescue mice from acute renal tubular damage under a conditioning advantage (irradiation or cisplatin treatment) favouring donor cell engraftment and regeneration; however, it is not known whether bone marrow cells (BMCs) can contribute to repair of acute tubular damage in the absence of a selection pressure for the donor cells. The aim of this study was to examine this possibility. Materials and methods : Ten-week-old female mice were assigned into control non-irradiated animals having only vehicle treatment, HgCl₂-treated non-irradiated mice, HgCl₂-treated non-irradiated mice infused with male BMCs 1 day after HgCl₂, and vehicle-treated mice with male BMCs. Tritiated thymidine was given 1 h before animal killing. Results : Donor BMCs could not alleviate non-irradiated mice from acute tubular damage caused by HgCl₂, deduced by no reduction in serum urea nitrogen combined with negligible cell engraftment. However, donor BMCs could home to the bone marrow and spleen and display proliferative activity. This is the first report to show that despite no preparative myeloablation of recipients, engrafted donor BMCs can synthesize DNA in the bone marrow and spleen. Conclusions : Exogenous BMCs do not rescue non-irradiated mice from acute renal tubular damage caused by HgCl₂, despite establishment of chimerism and cell proliferation in bone marrow and spleen.     

Cell population kinetics of thyroid follicular cells in infant rats

Abstract. T cell population kinetics of thyroid follicular cells in rats were studied by means of autoradiography and a statmokinetic technique. During the first fortnight after birth no significant changes in the mitotic index (MI) and labelling index (LI) were found. In the next 2 weeks a constant decrease in the number of proliferating cells occurs. In 10-day old animals 40% of the follicular cells were in the cell cycle (GF); 3.25 ± 0.77 (SEM) % in the S phase and 0.18 ± 0.04% in mitoses (MI). Day–night changes in the LI and mitotic rate (MR) indicated a peak value at 13.30 hours with a lowest value at 22.30 hours. The mean LI and MR averaged over the whole 24 hr were 3.1 ± 0.1% and 122.2 ± 18.1%, respectively. In 10-day old animals, using the fraction of labelled mitoses (FLM) method the median cell cycle time ( T _C) was 79 hr and the phase durations were T _G1—64.6 hr, T _s—8.2 hr and T _G2—5.1 hr. The decrease in the number of proliferating cells with the age of the animals is considered to be a result of both cell cycle prolongation and in growth fraction reduction.     

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.     

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.