Cell kinetics in the mouse esophageal epithelium in relation to the time of day

The kinetics of mouse esophageal epithelial cells was investigated throughout 90 h after a single injection of 3H-thymidine at 01 or at 13 h--the times of the peak and minimal magnitudes of the radioisotope index in the circadian rhythm of proliferation. The mitotic cycle parameters in the cells varied but insignificantly. For cells treated with 3H-thymidine at 01 h, T = 24.3 h, ts = 6 h, tG2 min = 1.5 h, tG2+ 1/2 M = 2.9 h and tG1+/2 M = 15.4 h; for those treated with 3H-thymidine at 13 h, T = 25.6 h, ts = 8.4 h, tG2 min = 1 h, tG2+ 1/2 M = 2.2 h, tG1+ 1/2 M = 15 h. Cells labeled at 01 h proliferated more actively for a long period of time as compared to those labeled at 13 h. The synchronism in undergoing several successive mitotic cycles was greater for cells labeled at the peak radioisotope index. The data obtained also suggest that the majority of cells enter the G0 phase after the completion of the first cycle. The duration of the G0 phase varies in different cell populations.     

Indices of mitotic cell division in sebaceous glands]

The main indices of mitotic cell division in rat sebaceous glands (external auditory meatus and tarsales gl.) were studied autoradiographically using H3-thymidine and with colchicine method. The duration of mitotic cycle and its separate phases, the number of cells involved in the proliferative pool, as well as the turnover of terminals of the epithelium in both the glands were stated to be nearly identical. The duration of the mitotic cycle was: T -- 28.1 hour; tG1 -- 18.64; tS -- 6.3; tG2 -- 1.80; tM -- 1.34 hours. The proliferative pool (Pc) -- 31.45%, turnover of the basal layer cells -- 89.25 hours. These indices for the stratified epithelium of excretory ducts were respectively; T -- 33.0 hours; tG1 -- 21.74; --8.06; tG2 -- 1.6; tM -- 1.6; Pc -- 26.8% and the turnover for the cells of the basal layer -- 123 hours. Thus, the sebaceous glands are to be regarded as organs where a rapid renovation of epithelia cells occurs.     

Flow cytometric evaluation of cell cycle characteristics during in vitro differentiation of chick embryo chondrocytes

The cell cycle kinetic characteristics of chick endochondral chondrocytes differentiating in vitro were studied by flow cytometry. In addition, the synthesis of type I and type X collagens of the same cells was evaluated by immunoprecipitation. Dedifferentiated cells, derived from chick embryo tibiae and grown attached to a substratum, were characterized by type I collagen synthesis, a high growth fraction (GF = 0.94), minimal cell loss factor (phi = 0.02), and a total cell cycle time of the proliferating cells of about 17 h (tG1 = 8 h, tS = 5 h, and tG2 + M = 4 h). Transfer of dedifferentiated cells to suspension culture on agarose-coated dishes induced differentiation to hypertrophic chondrocytes. These were characterized by type X collagen synthesis, a low growth fraction (GF = 0.52), maximal cell loss factor (phi = 1.0), and a total cell cycle time of the proliferating cells of about 73 h (tG1 = 53 h, tS = 12 h, and tG2 + M = 8 h). The transition from dedifferentiated chondrocytes to hypertrophic chondrocytes was accompanied by large increases of the duration of all the cell cycle phases and of the number of quiescent and degenerating cells. Associated with these alterations in cell cycle kinetics was a switch from type I to type X collagen synthesis. Further preliminary data suggest that the population of differentiating chondrocytes (a state between dedifferentiated and hypertrophic chondrocytes) comprises a heterogeneous population of fast and slow growing cells.     

Diurnal rhythm of cell proliferation at the late stages of precancerous changes in the liver induced by ortho-aminoazo-toluene]

Orthoaminoazotoluol was administered to mice for a period of nine months. Circadian rhythms of mitotic activity and the number of the DNA-synthesizing cells were determined by autoradiography (with the use of 3H-thymidine) at the second (adenomatous nodes) and the third (primary hepatoma) stages of carcinogenesis in the developing tumours and the surrounding liver parenchyma. The listed structures proved to have a single-peak rhythm of mitotic activity with the maximum of mitoses at 4-7 a. m.; the labeled nuclei circadian rhythm was double-peaked with the maximum at 7 p. m. and 4 a. m. The mean 24-hour values of both indices at the second and third stages of hepatocarcinogenesis were much greater than in the surrounding non-tumour tissue of the liver.     

Fully automated TV-image analysis of the cell-cycle: comparison of the PLM method with determinations of the percentage and the DNA content of labelled cells

A cell-cycle analysis based on a fully automated TV-image scanning system is proposed to replace the laborious PLM method. To compare the efficiency of the two procedures, cell-cycle parameters were assessed in Ehrlich (diploid and hyperdiploid), L-1210, and JB-1 mouse ascites tumours and in rat jejunal crypts. The percentages of labelled mitoses (PLM) were counted visually on Feulgen-stained autoradiographs obtained at various times after a single 3H-thymidine pulse. The fraction of labelled cells (P) and the DNA ratio of labelled and unlabelled cells were measured by TV-image analysis in the same slides and plotted against time. Within practical limits, TV-image analysis using the P-curve gives the same results as the PLM method. Using the P-curve has the important advantage that its first part, beginning at the time of 3H-thymidine injection and ending at the first maximum, furnishes more information about the cell cycle than the corresponding part of the PLM curve. It can be used to compute tG2M tS and the ratio of the growth faction index to the cell-cycle time (IP/tC) whereas the first part of the PLM-curve reveals only the length of the S-phase (tS). The IP/tC ratio is a readily accessible measure of growth and increases when the cells divide more frequently. Cell death rates may be neglected since the ratio is determined within less than the duration of one cell cycle. Moreover, the data from the first part of the P curve indicate whether there is a large non-growth fraction. If the non-growth fraction is small, i.e. if IP approximately 1, the P curve need only be measured until the first maximum is reached so that fewer samples and animals are required. If the non-growth fraction is large or unknown, the cell-cycle parameters are calculated by reference to the position and size not only of the first minimum and the first maximum, but also of the second minimum of the P curve.     

Temporary organization of the processes of cell reproduction in the HeLa culture]

Rhythmical changes of the DNA--synthesizing and dividing cells have been identified in Hela cultures in the stationary phase of the growth. The periods of these changes were not equal to 24 hours. Synchronous quantitative changes of the DNA-synthesizing and dividing cells and the similarity in the length of their frequency periods were observed. The parameters of culture mitotic cycle: T--27--31 hr, tG2min--2hr, tG2+1/2M--4hr, ts--11 hr, tG1+1/2M--12--16 hr.     

The dependence of the cytokinetic effects of alkylating antitumor preparations on the phase of the hepatocyte cell cycle in regenerating liver]

Effects of alkylating antitumor drugs on resting (G0 phase of cell cycle) and proliferating (G1, S, G2 and M phases) hepatocytes were studied in regenerating mouse liver. Cell cycle kinetics (fraction of labeled mitoses, labeling and mitotic indices) were determined by 3H-thymidine autoradiography. Dipin and fotrin as a DNA-damaging agents attack mainly resting (G0) and proliferating (G1) cells. Effect of the damage results in the inhibition of DNA synthesis and G2 phase arrest in the following mitotic cycle. An alkylating drug phopurin as well as ara-C both suppress the mitotic progression in proliferating hepatocytes and do not influence the resting cells.     

Cell population kinetics in pig epidermis: further studies

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 tS varied from 8 to 10 hr. The cell turnover times (tT) 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 tS for cells in L1 and L2 were 9.8 hr and 11.9 hr, respectively. tG2 + 1/2tM was 7.2 hr in L1 and 9.1 hr in L2.     

Effect of beta-adrenoreceptor blockade on cell division processes in the corneal and tongue epithelium of white rats with chronic oxygen starvation

A study was made of the changes in the mitotic activity, DNA synthesis, and the number of pathological mitoses after administration of the beta-adrenoblocker propranolol in the corneal and tongue epithelium of white rats kept in pressure chamber for 7 days (4 h daily) at a "height" of 9000 meters. The mitotic and the label indices (inclusion of 3H-thymidine by the epithelium nuclei) were analysed for mitotic activity and DNA synthesis, respectively. The experiments showed that the mitotic activity, DNA synthesis, the number of pathological mitoses were stabilized due to the propranolol administration.     

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.     

TURNOVER OF CELL-RENEWING POPULATIONS UNDERGOING CIRCADIAN RHYTHMS IN CELL PROLIFERATION

Evidence is presented in support of the concept of partial synchrony of cells as the cause for circadian rhythms in DNA synthesis and mitotic activity. The nonuniform age distribution of cells in cycle indicated that equations based on total asynchrony were not applicable for calculation of cytokinetic parameters in cellrenewing populations undergoing circadian rhythms. The integration of the circadian mitotic curve is introduced as a simple and accurate method for determination of proliferation rate and turnover time. An approximately linear increase in the labeling index following repeated injections of ³H-thymidine demonstrated that nearly 100% basal cells in hamster cheek pouch epithelia were in cycle during a turnover time. These experiments suggest that if there is a G₂ phase in cellrenewing tissues, this is short with respect to turnover time and that it may be a specific compartment where the control of cell proliferation operates.     

Mitotic cycle kinetics of root meristems of isolated barley embryos and intact seedlings. Labelling of nuclei by3H- thymidine and its cytogenetic consequences

The duration of the mitotic cycle and its individual phases was estimated in root meristems of isolated barley embryos and intact barley seedlings by means of pulse labelling with³H-thymidine and construction of labelled mitoses curve. The duration of the whole mitotic cycle in the cell population of root meristems of isolated barley embryos cultivated in the aerated liquid complete medium is 12.2 h. The mitotic cycle time of root meristems of intact barley seedlings, oultived in Petri dishes on wet blotting paper is 9.2 h. Most of root meristem cells belong to the fraction of rapidly proliferating cells, but this fraction exerts a high degree of variability by itself. Pulse treatment by³H-thymidine in our experimental conditions (74 kBq ml^-1 - or 2 μCi ml^-1, exposure 0.5 h) did not induoe any chromosomal aberrations in unlabelled cells and only a very low frequency of chromosomal aberrations in labelled cells. Measuring the cell population kinetics by pulse labelling with³H-thymidine can be used simultaneously with the study of induction of ohromosomal aberrations by mutagens.     

Interaction of the circadian rhythms of the functional activity of the hypophyseal-adrenal system and of the mitotic activity in the esophageal epithelium of rats with experimental hypo- and hypercorticism

In experimental hypercorticism the average daily concentration of glucocorticoids in blood plasma is 4 times higher than in control one, the amplitude of the circadian rhythm increases almost 3 times, the time of maximum concentration does not change. The adrenocorticotrophic hormone (ACTH) average circadian concentration decreases twofold. The adrenalectomy results in abrupt smoothing down of the circadian rhythm of glucocorticoids concentration and in increasing (in 2,4 times) of the average circadian concentration of ACTH. The pattern of circadian rhythm remains, however the acrophase of hormone secretion is shifted. The circadian rhythm of cells devision in esophagus epithelium changes. The maximum of mitotic index is absent in adrenalectomized rats and the amplitude of its circadian variations decreases. In experimental hypercorticism the biphase rhythm of mitoses in induced.     

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.     

Circadian Rhythms In the Epithelial Cells and the Pericryptal Fibroblast Sheath In Three Different Sites In the Murine Intestinal Tract

Variations in percentage labelling (LI) and mitotic activity (mitoses per crypt) have been studied over a 24-hr period in the epithelial cells and pericryptal fibroblast sheath (PCFS) of the small intestine, caecum, and colon of the mouse. All three tissues displayed clear, synchronized circadian rhythms in DNA-synthetic activity in both the epithelial cells and PCFS. Peak values were coincident within a tissue, but staggered between tissues. In the epithelial cells, peak mitotic values were found between 3 and 6 hr after the peak LI values. the low level of mitotic activity in the PCFS appeared to be synchronized with the rhythms in the adjacent epithelia. the epithelial cells of the lowest crypt third displayed the clearest circadian rhythms. However, the PCFS cells at all levels produced similar curves. A craniocaudal wave of proliferative activity is proposed.     

Diurnal biological rhythms in the cells of granulation tissue in a liver injury]

Under study were the diurnal biological rhythms in 37 young mature male Wistar rats and in 44 young mature female Wistar rats in the cells of the granulation tissue (fibroblasts) 4 and 9 days respectively after injuring the liver. The animals were killed in groups every 4 h during 1 day, and in the second series--during 2 days. The diurnal rhythm was found in the mitotic activity. The first peak of mitoses was observed at midday and the second one--at midnight. The second peak may be absent. It has been shown autoradiographically that the maximum intensive synthesis of DNA took place at 8'clock a. m., i. e. 4th. before the appearance of the first maximum of mitoses. The most intensive synthesis of proteins and sulphated mucopolysaccharides in fibroblasts took place at 4 p. m.     

Circadian rhythm of the mitotic activity and of the number of nuclei synthesizing DNA in sarcoma 37 in white mice]

Circadian variations in the frequency of mitoses and the number of nuclei labed with thymidine-H3 in sarcoma-37 of mice were investigated. It was shown that the circadian rhythm of mitotic activity was composed of diurnal variations in the frequency of labeled and unlabeled mitoses. The G2-phase of mitotic cycle of the cells with labeled mitosis was approximately one hour. The G2-phase of the cells with unlabed mitosis lasted four hours and more. It is suggested that there are two cell populations in sarcoma-37.     

Non-circadian periodicity in the duration of the cell cycle and the G1 phase in the hindlimb epidermis of the anuran tadpole, Rana pipiens

Using the percentage labeled mitoses method, seven cell cycle determinations were initiated at 6-hr intervals over a 36-hr span in order to see if the cell cycle in the tadpole hindlimb epidermis varied with time or showed rhythmicity. There was a pattern of two long cell cycles followed by a shorter one. Total cell cycle length (Tc) and the length of the G1 phase plus one-half of the mitotic time (TG1 + 1/2M) fluctuated the most, although only TG1 + 1/2M varied significantly with the Chi-square test. The proportion of TC spent in each phase was also calculated. Only TG1 + 1/2M/TC had statistically significant fluctuations with time. Rhythmicity was analyzed by a computer program using the method of least squares for cosine curve fitting. Statistically significant ultradian rhythms of 18.4 hr in TC, 18.5 hr in TG1 + 1/2M and 18.6 hr in TG1 + 1/2M/TC and the length of the DNA synthetic phase/total cell cycle length (TS/TC) were found. Circadian rhythmicity was not observed. The acrophases of the ultradian rhythms of TC and TG1 + 1/2M coincided, suggesting that the rhythm of TC was due mainly to variation in TG1 + 1/2M. In the absence of significant variation in TS, the longest phase of the cell cycle, whenever G1 + 1/2M was short, TS/TC increased, so that the 18.6 hr rhythm in TS/TC was also a result of the periodicity in TG1 + 1/2M.     

Analysis of the cell cycle in the root meristem of Allium cepa under the influence of ledakrin

The influence of a polish anticancer drug on the cell cycle using Allium test was studied. Methods of aceto-orcein squash slides, curve of labelled mitoses after 3H-thymidine incubation and cytophotometrics after Feulgen's reaction were employed. Ledakrin acts strongly antimitotically, but it does not block the cell cycle completely. The cytostatic activity of ledakrin results from its action on the interphase. The phases G1 and S are prolonged while M is unchanged after 6h incubation with ledakrin. During postincubation in water without ledakrin it was noted, at the beginning, that the mitotic activity decreases and it is brought about the lengthening of S and G2 phases. The duration of the cell cycle phases returns to the control level during further postincubation. The results of analysis of chromatin aberrations and the micronucleus test point to a mutagenic effect of ledakrin.     

The effect of chalone on the cell cycle in the epidermis during wound healing

A cut was made on the ear conch of mouse and an extract containing epidermal chalone was injected subcutaneously 2 days later. The time changes after the chalone administration in the number of cells labeled with ³H-thymidine, in the number of grains on labeled cells and in the number of mitoses within the regenerating epidermis surrounding the wound were investigated by means of autoradiography (ARG). Grain counts decreased temporarily in early phase (0–2 h) after chalone injection. This decrease in grain count resulted in a decrease in the number of labeled cells on the ARG of a short exposure but not in that on the ARG of a long exposure. A decrease in the number of labeled cells on the ARG of a long exposure was evident at 6 h when the grain counts reverted to a level similar to the control without chalone. The number of mitoses reached a minimum at 2 h and then recovered quickly, indicating a rapid disappearance of the inhibition of cells in G 2 from entering M phase. Mitoses decreased again thereafter, presumably as a result caused by inhibition of cells in the preceding S phase from completing DNA synthesis. The extract made similarly from liver or kidney affected neither the mitotic nor the DNA synthetic activities.These results indicate that the epidermal chalone or chalones inhibit the epidermal cell proliferation in, at least, 3 different processes of the cell cycle; the DNA synthesis in S phase, the transition from G 1 to S phase and the transition from G 2 to M phase.