CIRCADIAN RHYTHMS OF PRESUMPTIVE STEM CELLS IN THREE DIFFERENT EPITHELIA OF THE MOUSE

Variation in the percentage of labelled cells (LI), mitoses (MI) and apoptosis (AI: i.e. shrinkage necrosis) have been studied throughout a 24 hr period (40 min after labelling with ³H-TdR) for tongue epithelium, epidermis and intestinal epithelium in the mouse. A room with reversed light cycle was used to obtain data for half of the 24 hr period. All three tissues showed marked variations in LI with peak values between 24.00 and 03.00 hours. In the intestine a maximum value for MI was observed 3-6 hr after that for LI and with a maximum value for AI slightly later. In all three epithelia the circadian rhythm was most striking in cells at positions which can be correlated with presumptive stem cell activity; e.g. in the crypts the labelling and mitotic peaks reflecting a circadian rhythm were most clearly distinguishable at the basal part of the crypts. These observations are discussed in relation to the validity of various proliferative models.     

Heterogeneity in Cell Behaviour in Primordia ofVicia faba

The response of cells of small primordia ofVicia faba to³H-TdR and colchicine is discussed. The delayed uptake of³H-TdR shown by cells of small primordia appears to be a property of only 50% of the cells; the remaining never become capable of incorporating³H-TdR. Prom the labeled cells and polyploid cells induced by colchicine the shortest cycle time in small primordia is estimated to be 12 hours. Within a period equal to 1 mitotic cycle, 31–35% of all mitoses are tetraploid, following treatment with colchicine. The remainder are diploid and diploid mitoses were seen for up to 30 hours. These observations are indicative of a heterogeneity for mitotic cycle time in populations consisting of up to 1,500 cells. The percentage labeled mitosis curve of diploid cells was changed in primordia treated with colchicine; higher peaks were found. These results show that even small populations of cells, at the beginning of a morphogenetic system, are very heterogeneous for key cell properties. This research has been supported by the U.S.A.B.C. [AT (11-1) 1625-21].     

TRANSIT TIMES THROUGH THE CYCLE PHASES OF JEJUNAL CRYPT CELLS OF THE MOUSE ANALYSIS IN TERMS OF THE MEAN VALUES AND THE VARIANCES

Mean transit times as well as variances of the transit times through the individual phases of the cell cycle have been determined for the crypt epithelial cells of the jejunum of the mouse. To achieve this the fraction of labelled mitoses (FLM) technique has been modified by double labelling with [³H] and [¹⁴C]thymidine. Mice were given a first injection of [³H]thymidine, and 2 hr later a second injection of [¹⁴C]thymidine. This produces a narrow subpopulation of purely ³H-labelled cells at the beginning of G₂-phase and a corresponding subpopulation of purely ¹⁴C-labelled cells at the beginning of the S-phase. When these two subpopulations progress through the cell cycle, one obtains FLM waves of purely ³H- and purely ¹⁴C-labelled mitoses. These waves have considerably better resolution than the conventional FLM-curves. From the temporal positions of the observed maxima the mean transit times of the cells through the individual phases of the cycle can be determined. Moreover one obtains from the width of the individual waves the variances of the transit times through the individual phases. It has been found, that the variances of the transit times through successive phases are additive. This indicates that the transit times of cells through successive phases are independently distributed. This statistical independence is an implicit assumption in most of the models applied to the analysis of FLM curves, however there had previously been no experimental support of this assumption. A further result is, that the variance of the transit time through any phase of the cycle is proportional to the mean transit time. This implies that the progress of the crypt epithelial cells is subject to an equal degree of randomness in the various phases of the cycle.     

Circadian rhythms of folate and vitamin B12 concentration in relation to convulsive thresholds of mice

Circadian rhythms of folate and vitamin B₁₂ concentrations in the liver, brain and blood of Swiss mice have been determined. The relation of the changes in vitamin concentration to circadian rhythms in locomotor activity, drinking activity and convulsive thresholds (maximal electroshock seizure threshold) have been determined also. Both free folic acid (FFA) and total folic acid (TFA) of liver and blood showed minimum values at 21.00–24.00 h and maximum values at 06.00–09.00 h. Liver TFA declined at a steady rate from the peak value at 09.00 h whereas liver FFA and plasma folate maintained constant values from 09.00–18.00 h then declined rapidly. Brain folate (TFA and FFA) showed no rhythm. The concentrations of vitamin B₁₂ in plasma, liver and brain showed only minor fluctuations. Locomotor and drinking activities showed very similar rhythms with a sustained period of high activity between 12.00–21.00 h followed by a much shorter second period of high activity (23.00–03.00 h). Convulsive threshold declined during the first period of increased locomotor and drinking activities reaching a minimum value at 21.00 h thus just preceding the nadir in folate concentrations in liver and blood.     

Growth Fraction and Cycle Duration of Hepatocytes In the Three-Week-Old Rat

The proliferation of hepatocytes in the liver of 3-week-old rats has been investigated by autoradiographic methods. This investigation is a continuation of earlier work on the same topic (Schultze & Maurer, 1972; 1973). 21 days after birth, 102 rats received a single injection of ³H-TdR. the percentage of labelled mitoses was then determined 1 hr later and at various times throughout the interval up to 12 days after application of ³H-TdR. In agreement with earlier work, a first peak of labelled mitoses was found 7 hr after ³H-TdR injection. the area under the peak indicates an S phase duration of 8 hr. In addition a second very broad peak of labelled mitoses was found between 2 and 12 days after pulse labelling. the analysis of the results leads to the conclusion that the hepatocytes of the 3-week-old rat have a growth fraction close to 1 and a doubling time of 6–7 days. This is at variance with earlier results of Post, Huang & Hoffman (1963) and Grisham (1969) who had derived a value of 21.5 hr for the duration of the cell cycle and a value of only 0. 1–0.2 for the growth fraction of the hepatocytes.     

Mitotic and Labelling Activity In Normal Human Epidermis In Vivo

Labelling and mitotic indices were studied in the epidermis of twenty-eight young men. A mean labelling index of 5.5% was found from the whole study and a mean mitotic index of 0.06%. Mitotic index particularly was extremely variable; indices between 0.002 and 0.438% were found in individual biopsies. In the first two of three experiments in which mitotic index at 09.00 hours was compared with that at 15.00 hours, significant differences were found (15.00 hours > 09.00 hours by a factor of 2.6, P < 0.001). However, in the third such experiment no such difference was found, suggesting that the timing and occurrence of diurnal rhythms of mitotic activity may not be consistent in normal human epidermis. In the one experiment in which it was investigated, a significantly higher mitotic index was found at 21.00 hours compared to 09.00 and 15.00 hours. Labelling index did not vary significantly at 09.00, 15.00 or 21.00 hours. However, labelling index did show a significant pattern of change over a 12-month period in two groups of subjects; peaks of labelling were seen in July and troughs in January. Very high ratios of labelled: mitotic cells were found, the median ratio for the whole study being ninety-eight labelled: one mitotic cell. This finding supports the possibility that not all labelled cells subsequently go on to divide in normal human epidermis.     

A TECHNIQUE FOR DETERMINING THE PROPORTION OF THE CLONOGENIC CELLS IN S PHASE IN EMT6 CELL CULTURES AND TUMORS

The survival of cultured EMT6 cells was examined after treatment with hydroxyurea (HU) or high specific activity tritiated thymidine (³H-TdR). The concentrations of the agents, duration of exposure to the agents, and post-exposure treatment of the cultures were found to influence the cell survival; the effects of these factors are reported. Conditions were defined under which the proportions of cells killed by HU and by ³H-TdR were the same and were also the same as the proportion of labeled cells seen on autoradiographs of cultures labeled with small doses of ³H-TdR. Under these conditions, either ³H-TdR or HU could be used to determine the proportion of the clonogenic cells in S phase. Single cell suspensions prepared from solid EMT6 tumors were treated in vitro with HU or ³H-TdR, using the conditions found optimal for each agent with cultured cells. The proportion of the tumor cells killed by treatment with HU in vitro was the same as the proportion killed by HU in vivo and as the proportion labeled by ³H-TdR in vivo, and incubation of tumor cell suspensions with HU in vitro appeared to provide a valid measurement of the proportion of clonogenic tumor cells in S phase. Incubation of tumor cell suspensions with ³H-TdR in vitro proved difficult to perform and the results were relatively unreliable because of severe problems with reutilization of ³H-TdR during the incubation for colony formation.     

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.     

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 rhythms in the incidence of apoptotic cells and number of clonogenic cells in intestinal crypts after radiation using normal and reversed light conditions

Variations in the number of radiation-induced morphologically dead or dying cells (apoptotic cells) in the crypts in the small intestine of the mouse have been studied throughout a 24-h period under a normal light regimen (light on, 07.00-19.00 h; light off, 19.00-07.00 h). A clear circadian rhythm was displayed in the apoptotic incidence 3 or 6 h after irradiation for each gamma-ray dose studied (range 0.14-9.0 Gy). The most prominent circadian rhythm was obtained after 0.5 Gy. The peak time of day for inducing apoptosis was 06.00-09.00 h, and the trough occurred at 18.00-21.00 h. Some mice were also transferred to a room with the light cycle reversed, and were irradiated on different days after the transfer. The apoptosis induced by 0.5 Gy or 9.0 Gy, or the number of surviving crypts (microcolonies) after 11.0 Gy or 13.0 Gy was examined. The transition point for reversal (i.e. the switch time from the normal-light pattern to the reversed-light pattern) of the circadian rhythm in apoptosis (after 0.5 Gy) occurred 7 days after the transfer and the rhythm was reversed by 14 days. The rhythm for crypt survival (i.e. for clonogenic cell radiosensitivity) was disturbed on 1 day and the transition point for reversal occurred 3 days after the transfer. The rhythm became reversed by 7 days. These observations are discussed in relation to the identity of clonogenic cells, (functional) stem cells, proliferating transit cells and the cells sensitive to small doses of radiation (i.e. hypersensitive cells) in the crypt.     

CELL KINETICS OF IRRADIATED EXPERIMENTAL TUMORS: CELL TRANSITION FROM THE NON-PROLIFERATING TO THE PROLIFERATING POOL

Parenchymal tumor cells of murine mammary carcinomas can be divided into two pools, using nucleoli as morphological ‘markers’. Cells with dense nucleoli traverse the cell cycle and divide, thus constituting the proliferating pool. Cells with trabeculate or ring-shaped nucleoli either proceed slowly through G₁ phase or are arrested in it. The role of these non-proliferating, G₁ phase-confined cells in tumor regeneration was studied in vivo after a subcurative dose of X-irradiation in two transplantable tumor lines. Tumor-bearing mice were continuously injected with methyl[³H]thymidine before and after irradiation. Finally, the labeling was discontinued, mice injected with vincristine sulfate and cells arrested in metaphase were accumulated over a 10-hr period. Two clearly delineated groups of vincristinearrested mitoses emerged in autoradiograms prepared from tumor tissue at the time of starting tumor regrowth: one group with the silver-grain counts corresponding to the background level, the other with heavily labeled mitoses. As the only source of unlabeled mitoses was unlabeled G₁ phase-confined cells persisting in the tumor, this observation indicated cell transition from the non-proliferating to the proliferating pool, which took place in the initial phase of the tumor regrowth. Unlabeled progenitors have apparently remained in G₁ phase for at least 5–12 days after irradiation.     

EFFECT OF METHOTREXATE ON THE CELL CYCLE OF L1210 LEUKEMIA

The influence of methotrexate (MTX) on the proliferative activity of cells in different phases of cell cycle has been studied. MTX (5 mg/kg) was injected i.p. 3 days after the inoculation of 5 × 10⁶ leukemia cells into F₁ (DBA × C57 BL) mice. It was shown that MTX causes degeneration of cells, being in G₁- as well as in S-phase at the time of drug injection. Incorporation of ³H-TdR was suppressed for a period ranging from 2 to 12 hr after MTX administration, which is demonstrated by the decrease in the number of grains per cell. The number of cells labeled after ³H-TdR injection was also sharply decreased during this period. For a period of 3 until 15 hr after MTX administration the mitotic index decreased significantly as a result of inhibition of DNA synthesis. The blocking of the G₁-S transition was evident during 4 hr after MTX. Thereafter the G₁-S transition proceeds at a rate which is practically equal to that for nontreated controls. MTX did not inhibit transition to mitosis of cells being in G₂-phase and in a very late S-phase at the time of drug injection. The sensitivity of G₁-cells to the cytocidal effect of MTX shows that for L1210 leukemia cells MTX can be classified as a cycle-specific drug killing both G₁ and S-cells rather than S-phase specific agent with self-limitation.     

PROLIFERATION OF ERYTHROID AND GRANULOCYTE PROGENITORS IN THE SPLEEN AS A FUNCTION OF STEM CELL DOSE

A study of the kinetics of cellular proliferation, in the morphologically unrecognizable haemopoietic progenitor cell compartment, as a function of injected CFU-S dose has been carried out in the spleens of lethally X-irradiated mice using ³H-TdR labelling. Amplification in this proliferating cell compartment was observed to decline as CFU-S dose increased. The number of divisions in the differentiated line arising from CFU-S up to the first appearance of recognizable erythroid precursors were calculated to be 9.2, 12.5, 15 and 17 for the 2, 0.35, 0.05 and 0.007 femur equivalent doses respectively. The growth of cell populations arising from CFU-S was biphasic, with a rapid initial phase having a doubling time of about 6.3 hr, and a slow phase of doubling time around 1 day. Analysis of the rapid phase by the FLM method gave a cycle time of 5.6 hr. Recognizable labelled erythroid precursors were detected at the same time as, or just after, the change in slope of the growth curve. Significant numbers of proliferating (labelled) granulocytes only appeared in the spleens of animals receiving the higher marrow doses (2 and 0.35 femur). The erythroid to granulocyte ratio was also a decreasing function of marrow dose.     

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

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. 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 colchicine 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.     

ON THE PERSISTENCE OF OOCYTE NUCLEI FROM FETUS TO MATURITY IN THE LABORATORY MOUSE

Tritiated thymidine injected intraperitoneally into female mice midway through the gestation period was demonstrated by autoradiographic methods to be incorporated into the nuclei of oocytes of female embryos, observed at the pachytene stage of meiosis 2 to 4 days after the injection. The tritium label was also demonstrated in the oocyte nuclei of the daughters of similarly treated females at maturity (6 weeks post partum). It was also found that some follicle cells, likewise labeled with H³-thymidine in mid-fetal life, persisted to maturity with few or no intervening mitoses. The observations are presented in support of the prevailing view that individual oocytes which arise from germ cell primordia in fetal stages become the egg cells of the adult female mammal.     

RADIOTOXICITY OF INCORPORATED [3H]THYMIDINE AS STUDIED BY AUTORADIOGRAPHY AND FLOW CYTOMETRY CONSEQUENCES FOR THE INTERPRETATION OF FLM DATA

The radiotoxic effects of incorporated [³H]thymidine on proliferation kinetics of flash-labelled (30 min, 0.3 μCi/ml, 40 Ci/mM) L-929 cells in vitro were studied by means of autoradiography and flow cytometry. the flow cytometric results obtained by applying the BUdR-33258 Hoechst technique, using new evaluation procedures, showed that the labelled cells are delayed in their progression through the S and G₂+ M phases, leading to mitotic delay. From autoradiographs, the fraction of labelled mitoses was determined and, in addition, the ratio of labelled and of unlabelled mitotic cells to all cells. the radiotoxic effects are not evident from the FLM curve, even if the ratio of labelled mitotic cells to all cells shows a highly distorted shape. A mathematical model has been developed that describes the perturbed cell kinetics due to radiotoxic effects of the incorporated [³H]thymidine. These findings have considerable consequences for the interpretation of autoradiograhic data, especially of labelled mitoses curves.     

EFFECTS OF UTERINE DISTENSION AND OESTRADIOL ON CELL KINETICS IN THE ENDOMETRIAL EPITHELIUM OF OVARIECTOMIZED RATS

Cell kinetics in the uterine epithelium of ovariectomized rats were studied after uterine distension and/or an oestradiol injection, by cumulative ³H-TdR labelling and percentage of labelled mitoses (PLM). With both methods it was found that distension shortens the total cell cycle at the expense of G₁ more than does oestradiol. Both treatments act in a cumulative manner since the greatest reduction in T_c is observed after distension plus oestradiol. PLM curves showed that distension and/or oestradiol induce a 30% reduction in S phase duration. The evolution of percentages of labelled cells and colchicine-blocked mitoses after these treatments confirms their additive effects and indicates that the mitogenic action of oestradiol is delayed compared to that of distension. It is suggested that these factors stimulate epithelial cell division in the uterus through partly different metabolic channels.     

Mitotic and labelling activity in normal human epidermis in vivo

Labelling and mitotic indices were studied in the epidermis of twenty-eight young men. A mean labelling index of 5.5% was found from the whole study and a mean mitotic index of 0.06%. Mitotic index particularly was extremely variable; indices between 0.002 and 0.438% were found in individual biopsies. In the first two of three experiments in which mitotic index at 09.00 hours was compared with that at 15.00 hours, significant differences were found (15.00 hours greater than 09.00 hours by a factor of 2.6, P less than 0.001). However, in the third such experiment no such difference was found, suggesting that the timing and occurrence of diurnal rhythms of mitotic activity may not be consistent in normal human epidermis. In the one experiment in which it was investigated, a significantly higher mitotic index was found at 21.00 hours compared to 09.00 and 15.00 hours. Labelling index did not vary significantly at 09.00, 15.00 or 21.00 hours. However, labelling index did show a significant pattern of change over a 12-month period in two groups of subjects; peaks of labelling were seen in July and troughs in January. Very high ratios of labelled: mitotic cells were found, the median ratio for the whole study being ninety-eight labelled: one mitotic cell. This finding supports the possibility that not all labelled cells subsequently go on to divide in normal human epidermis.     

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.     

Quantitative study of circadian variations in mast cell number in different regions of the mouse

The tongue, pinna and dorsal skin of adult male C-1 mice were removed at 03.00, 06.00, 09.00, 12.00, 15.00, 18.00, 21.00 and 24.00 h, fixed in basic lead acetate and stained with Alcian blue-safranin or 0.5% toluidine blue. The mast cell numbers of these regions were counted and analyzed statistically by analysis of variance. It was found that there were circadian variations in the mast cell number in the tongue, pinna and dorsal skin. The difference between the minimum and maximum of circadian variation in mast cell number in all three regions was highly significant (p less than 0.01). Furthermore, the time points of the maximum and minimum of mast cell number varied between the different regions. The time point of the minimum in the tongue and pinna was at 06.00 h, whereas it was at 09.00 h in the dorsal skin. The time point of the maximum in the tongue and dorsal skin was at 21.00 h, but in the pinna it was at 18.00 h.