Mitotic activity of regenerating rat liver following stimulation with alpha- and beta-adrenoreceptors

A study was made of the effect of stimulating alpha- and beta-adrenoreceptors on the mitotic activity of the rat regenerating liver following resection. Mesaton, a stimulator of alpha-adrenoreceptors, and isadrin, a stimulator of beta-adrenoreceptors, in a dose of 0.2 mg/kg were injected one hour before liver resection or 30 min, 8 and 24 h after operation. In all experimental groups, mesaton gave rise to an increase in the mitotic index without lowering the coefficient of the mitotic phases. The least pronounced stimulating effect was attained when mesaton was injected 9 hours after partial hepatectomy. Isadrin reduced the mitotic activity as judged from the decrease of the coefficient of the phases and augmentation of the number of binuclear cells. The experiments confirmed a previously advanced assumption that stimulation of alpha-adrenoreceptors favours while that of beta-adrenoreceptors reduces cell proliferation.     

Effect of adrenoreceptor blockaders on the mitotic activity of regenerating liver]

One hour before resection of the liver and repeatedly 24 hours after the operation male rats were given phentholamine--a blocker of alpha-adrenoceptors; this preparation inhibited the mitotic activity of the regenerating liver. A double administration at the same periods of propanol--a blocker of beta-adrenoceptors--caused an elevation of the mitotic activity. A conclusion was drawn that by stimulation of beta-adrenoceptors it was possible to inhibit the regenerative process. Adrenaline stimulated this process by acting through beta-adrenoceptors.     

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.     

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.     

Proliferative activity of Shvetz tumor following single and repeated irradiation]

Autoradiographic study of an experimentally-induced tumour following local irradiation in a dose of 600 rad showed no retardation of the cell cycle 6 to 12 hours after the irradiation. Marked reduction of the mitotic index (MI) and of the labeled nuclei index (LNI) was noted to the 96th hour after the irradiation. In repeated irradiation in a dose of 1200 rad at an interval of 18 hours there was revealed a marked reduction of the MI and of the LNI as a result of the block of the passage of cells from the G1-period into S. However, restoration of the cell proliferation uas noted by the 24th-48th hours. A high MI revealed at all the periods of investigation after repeated tumour irradiation at an interval of 24 hours was possibly caused by an increase in the time of mitosis proper, this also being confirmed by a significant accumulation of the number of late mitotic phases.     

The effect of 5-fluorouracil on the mitotic cycle and DNA synthesis in the epithelium of mouse small intestine.

The examinations were performed on 42 mice of the Porton strain. The experimental animals were injected intraperitoneally with the dose of 75 mg of 5-fluorouracil per kg body weight. The first experimental group received injections of [3H]thymidine within 48 hours and the second group within 96 hours of the injection of 5-fluorouracil. Two mice from each group were killed at within 1, 2, 4, 8, 12, 24, and 48 hours of the [3H]thymidine injection. Calculations of the mitotic index and time of duration of individual phases of the mitotic cycle in epithelial cells of the small intestine were based on application of the autoradiographic method. These studies lead to the conclusion that 5-fluorouracil disturbs the course of metabolic processes in the cell, which are also related with the distribution of the genetic material. Histological examinations show that 5-fluorouracil produces profound morphological changes in the intestine, which affect both the intestinal epithelium and the connective tissue stroma. The autoradiographic tests revealed a considerable suppression of the mitotic activity of the epithelium of intestinal crypts. Moreover, it was shown that 5-fluorouracil inhibits the mitotic activity of the intestinal epithelium by diminishing the number of cells capable of entering into mitosis. Nevertheless, by 96 hours following introduction of a single dose of 5-fluorouracil normal morphological structure and mitotic activity of the intestinal wall cells are restored.     

Species-specific aggregation factor in sponges. V. Influence on programmed syntheses.

Isolated cells from the siliceous sponge Geodia cydonium as well as small primary aggregates (diameter: 70 mum) consisting of them show no increase in rates of programmed syntheses and mitotic activity with time. After addition of a highly purified aggregation factor to a culture with primary aggregates which subsequently form secondary aggregates (diameter: larger than 1000 mum), a dramatic increase of DNA, RNA and protein synthesis occurs. Together with this increase, the cells show a high mitotic activity. The values for the mitotic coefficient reach a first maximum 8 h after the beginning of the secondary aggregation process. The stimulation of the mitotic activity of cells during the aggregation factor induced secondary aggregation process can be suppressed by inhibitors of RNA and protein synthesis as well as by a blocker of DNA synthesis. This finding may indicate that cells from the G0-population enter the proliferating cell pool via the G1-phase.     

Conditions of the reversibility of metaphase arrest and induction of multi-polar mitoses after treatment with nocodazole

Nocodazole at a concentration 0.02 mcg/ml or higher arrests PE cells (pig kidney embryo cells) in K-metaphase. Accumulation of mitotic cells by incubation with 0.02 or 0.6 mcg/ml nocodazole occurs linearly and at the same rate during 12-16 hours. After nocodazole is removed, the mitotic index is resumed to the normal rate. The maximum time of the reversible mitotic arrest in PE cells in 16 hours. After the incubation of cells with 0.2 mcg/ml nocodazole, the time of the reversible mitotic arrest is 12 hours. After the incubation of cells with 0.02 or 0.2 mcg/ml nocodazole, no multipolar mitoses are observed. After the 4 hours incubation with 0.6 mcg/ml nocodazole, multipolar mitotic figures are observed 1.5-2.5 hours after drug removal. It is concluded that the induction of multipolar divisions requires no prolonged mitotic arrest, but it may be caused by a complete depolymerization of spindle microtubules.     

Circadian rhythm of hepatoma 22a cell division after exposure to liver chalone

Chalone isolated from the cells of the normal rat liver exerts a pronounced inhibitory action on hepatoma 22a cell division during 9 hours after its administration. Then the mitotic activity of hepatoma cells returns to the control level, but after 15 hours it starts to diminish again. The total amount of cells that entered the mitotic cycle during the experiment declined by 30% as compared to the control. Thus, hepatic chalone produces a reversible inhibition of hepatoma cell division in G2 and G1 phases of the mitotic cycle and lessens the fraction of dividing cells over a period of 24 hours.     

Effect of a stable analog of leu-enkephalin, dalargin, on the cell division of the corneal epithelium in white rats

The effect of Leu-enkephalin analog--dalargin--on the corneal epithelium proliferation has been studied in white rats. 10 microliter dalargin per 1 kg body weight were administered intraperitoneally at 8 a.m. The mitotic index (MI), DNA synthesis cell index and label intensity (LI) were determined every 4 hours over a 24-hour period. The results obtained demonstrate that dalargin stimulates DNA synthesis in cells throughout the entire period of action. MI increased only 4, 8, 12 hours after dalargin administration. Mean daily DNA synthesis cell index and MI increased 2.1-fold and 3.1-fold, respectively after dalargin administration. It is suggested that dalargin activates the cell division processes by speeding up mitosis, shortening the premitotic period, accelerating the speed of the DNA synthesis and increasing cell proliferation pool.     

Determination of the mitotic index by microinjection of fluorescently labelled tubulin

The microneedle injection technique is one of the most established procedures for the introduction of proteins into living cells. To analyse injected proteins which are important in cell cycle progression it is often necessary to determine the mitotic index. Measuring the mitotic index after microinjection is complicated because only a limited number of cells of the whole cell population is microinjected. Therefore, we attempted to establish a new method to determine the mitotic index using microinjection of fluorescently labelled alpha/beta-tubulin into mammalian cells which allows to monitor the injected cells simultaneously with the determination of the mitotic index. We demonstrated that fluorescently labelled tubulin incorporates efficiently into the mitotic spindle apparatus. Fluorescence remains stable for several hours which is sufficient to observe the progression of cells through the M-phase of the cell cycle. The determination of the mitotic index with the method presented here gave similar results to those determined using other methods. With this method also different stages of mitosis can be visualized by analysing various steps of spindle formation. Thus, this rapid method allows the monitoring of the injected cells after microneedle injection and simultaneously the determination of the mitotic index.     

Cellular ultrastructure of the hepatic sinusoid in partially hepatectomized rats

In male Wistar rats weighing 160-200 g 2/3 of the liver tissue was removed. As a result the phase modifications of lysosome structures in Kupffer's cells have been observed. 2.5 hours after operation the number of primary lysosomal granules increased, 9 hours later an augmentation in size and polymorphism of lysosomes was revealed. At the moment of hepatocyte mitotic peak, i. e. 30 hours after partial liver removal mainly secondary lysosomes were detected in Kupffer's cells. On the contrary, 48 hours following operation the number of new wave of accumulation of primary lysosomal granules was seen. In endothelial cells the lipid infiltration was prevalent especially at the hepatocyte mitotic peak period. The data obtained indicate specific relationship of ultrastructural modifications in sinusoidal cells and phases of the liver reparative regeneration.     

Cytological analysis of the intact and regenerating liver of different strains of rats]

Comparative cytological studies were conducted on control and regenerating liver of two strains (August and Cotton) of rats, 2/3 of the liver was resected; 5 or 6 animals were sacrificed at each of the following postoperative periods: in 30 hours, 3, 8, 42 and 120 days. The number of binuclear cells, the size of mononuclear hepatocytes and their nuclei, the mitotic activity, and ploidity of hepatocytes were determined. The intact and regenerating liver of the August rats differed from the intact and regenerating liver of the Cotton rats by a number of cytological indices, excluding the mitotic activity. A conclusion was drawn that the observed interstrain differences in the cytological indices providing regeneration of the liver after resection in the August and Cotton rats depended on the genotype of the given strain.     

Cell cycles in the early embryogenesis of the peled]

The dynamics of cell cycles in early embryogenesis of the peled has been studied using various methofs: determination of mitotic and mitotic phase index, of cell doubling time and of coefficient of asynchrony. The desynchronization of divisions begins at the V division after the longitudinal furrow has passed and is completed after the beginning of the cell cycle lengthening. The animal-vegetative gradient in the distribution of mitotic phases is observed at the early stages of desynchronization. The lengthening of cell cycle begins in interphase of the XI-XII cleavage and markedly accelerates from the interphase of the XII-XIII cleavage on. The methods of analysis of the cell cycles in early embryogenesis and possible factors influencing the dynamics of desynchronization are discussed.     

Effect of an extract of mouse Ehrlich ascitic tumor cells on mitotic activity and DNA synthesis in that tumor]

The extract of Ehrlich's ascitis tumour cells depressed specifically the proliferative activity of this tumour cells. This was expressed in a marked reduction in the number of dividing and DNA-synthesizing cells after the extract injection. The mitotic index fell considerably as soon as 2 hours after the injection, reached the minimum in 4 to 5 hours and was restored to the control level in 9 to 12 hours. The radioactive index appeared to be evenly decreased in the course of 18 hours of the experiment.     

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.     

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.     

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.     

A Stochastic Model For Cell Populations With Circadian Rhythms

A mathematical model for cell kinetics, based on a random walk, is developed. the model allows variations with time of the rates of passage of proliferating cells through the four phases of the mitotic cycle. Circadian variations in the mitotic and labelling indices of the Syrian hamster cheek pouch epithelium have previously been observed, and the random walk model has been used to simulate this phenomenon. Assuming that all basal cells are proliferative and that these cells leave the basal layer randomly throughout the mitotic cycle to become differentiated cells, it was found that the experimentally observed circadian rhythms of the mitotic and labelling indices could be reproduced in the model by postulating a circadian rhythm in the rate of passage of cells through the G₁ and S phases only. Moreover, the growth activity of cells in both the G₁ and S phases appears to reach a peak during the dark hours of the light-dark cycle, and to fall off rapidly in the early hours of daylight. the postulate of Møller, Larsen & Faber (1974) that injection of the animals with tritiated thymidine causes a shortening of the G₂ phase duration has been qualitatively confirmed by using the random walk model to simulate the FLM and MI curves after injection with tritiated thymidine.     

Cell population kinetics and the cell population mechanisms of the circadian rhythm of proliferative activity in mouse esophageal epithelium]

The dynamics of 3H-thymidine labeled mitosis and diurnal rhythm of proliferative activity was studied. The isotope was injected to BALB/C mice at the peak of diurnal rhythm of DNA synthesis activity of basal layer cells of oesophageus epithelium. It has been established that the increase in the mitotic index during 24 hours depends on the increase in number of cells being in S-period. The data show that the increase of mitotic index at diurnal rhythm occurs at the expense of 75% of new G0-cells which entered into the mitotic cycle, and of 25% of re-entering cells that had divided during the maximal mitotic activity a day before. It is found that the duration of mitotic cycle of cell population which entered into the mitotic cycle synchronously is almost equal to the period of diurnal rhythm of mitotic activity, i.e. 24 hours.