Synchronization of the Human Promyelocytic Cell Line HL 60 By Thymidine

Cultures of the promyelocytic cell line HL 60 were synchronized with thymidine. A concentration of 0.05 mM thymidine and an exposure time of 24 hr was found optimal for blocking about 90% of the cells in S phase. Following release from the thymidine block the cell cultures were followed intermittently over 40 hr for fluctuation in cell numbers, labelling with radioactive thymidine and nuclear DNA distributions. Mathematical evaluation of the results revealed a cycling time of 18.6 hr and a duration of specific cell phases of 8.6 hr, 7.1 hr and 2.9 hr for G₁, S and G₂+ M, respectively. the doubling time was 26 hr and the growth fraction was estimated as 1.     

Synchronization of the human promyelocytic cell line HL 60 by thymidine

Cultures of the promyelocytic cell line HL 60 were synchronized with thymidine. A concentration of 0.05 mM thymidine and an exposure time of 24 hr was found optimal for blocking about 90% of the cells in S phase. Following release from the thymidine block the cell cultures were followed intermittently over 40 hr for fluctuation in cell numbers, labelling with radioactive thymidine and nuclear DNA distributions. Mathematical evaluation of the results revealed a cycling time of 18.6 hr and a duration of specific cell phases of 8.6 hr, 7.1 hr and 2.9 hr for G1, S and G2 + M, respectively. The doubling time was 26 hr and the growth fraction was estimated as 1.     

OBSERVATIONS ON HUMAN MONOCYTE KINETICS AFTER PULSE LABELING

Monocyte kinetics were studied in seven hematologically normal individuals using in vivo pulse labeling with tritiated thymidine. Although occasional labeled cells appear in the peripheral blood within 4 or 5 hr of the administration of label, a significant outflow from the marrow begins 13–26 hr later. This interval is occupied by the G₂ and M phases of the mitotic cycle since mitotic cells are not observed in the peripheral blood. The duration of the DNA synthesis phase of monocytes is measured at 34 hr ≈ 1.8 hr. Cells do not enter this phase while circulating since exposure of circulating cells to tritiated thymidine does not result in any uptake. If monocytes are not 'end'cells which have completed their mitotic activity before leaving the marrow they must at least be inhibited from further proliferative activity until they are permanently sequestered in other tissues.
The generation time is probably not less than 40 hr and data derived from the mean grain counts of labeled cells suggest that it is often more than 70 hr. The total daily output of monocytes in man is 9.4 × 10⁸ cells per 24 hr ≈ 3.3 × 10⁸.
Cells leave the bloodstream with a half-time of about 71 hr thereby proving themselves to be considerably more durable than neutrophils which have a half-life in the neighborhood of 6 hr.     

DNA synthesis in cultured human fibroblasts: Regulation by 3′ : 5′-cyclic amp

The addition of serum to density-inhibited human fibroblast cultures induced a wave of DNA synthesis, measured as [³H] thymidine incorporation into acid-precipitable material, beginning after 8–12 hr and reaching maximum levels at 16–24 hr. Addition of dibutyryl-3′ : 5′-cyclic AMP (DBcAMP) together with serum inhibited [³H] thymidine incorporation by 75–95%. When DBcAMP was added for the first 4 hr of serum stimulation and then removed, the wave of DNA synthesis was not delayed. This suggested that serum could induce DNA synthesis even though cyclic AMP concentrations were maintained at high levels by DBcAMP during this initial period. These results are inconsistent with the hypothesis that it is the immediate transient reduction in 3′ : 5′-cyclic AMP concentration following the addition of serum that triggers DNA synthesis. By contrast, DBcAMP added 8 hr after serum inhibited [³H] thymidine incorporation to the same extent as DBcAMP added at the same time as serum. This indicated that a step essential for DNA synthesis and occurring late in G₁ was inhibited by high concentrations of 3′ : 5′-cyclic AMP.     

The induction of transient increases in mitotic rate in murine tissues following prolonged intravenous infusions of hydroxyurea.

Intravenous infusions of hydroxyurea were established in mice and maintained for periods up to 48 hr. The influence of different rates of hydroxyurea infusion on the number of viable cells gathered in S phase was studied in eight different mouse tissues. An infusion rate which was sufficiently slow not to block thymidine incorporation completely, resulted in gathering of cells in S phase while offering some protection against hydroxyurea-induced cell death. The duration of the period of DNA synthesis following release from hydroxyurea inhibition appeared to be shortened in some tissues. After the release of hydroxyurea blockades maintained for 12-24 hr, each of the tissues showed sharp increases in mitotic activity and peak mitotic index values were as much as twenty times greater than values found in tissues of control animals. An important finding was that the time of maximal mitotic activity for different tissues after release of blockade could differ by many hours.     

EFFECT OF AN INHIBITING FACTOR ISOLATED FROM RAT LIVER ON DNA POLYMERASES IN REGENERATING RAT LIVER

We partially purified an inhibitory factor (LIF), isolated from 105,000 g supernatant of a saline adult rat liver homogenate. LIF stopped in vitro cell multiplication by blocking the G₁—S transition, and reduced in vivo [³H]thymidine incorporation into liver DNA in two-thirds hepatectomized rats. This reduction in DNA synthesis was observed at 24 hr after hepatectomy, even when the LIF was injected before the beginning of the S phase, 10 hr after hepatectomy, i.e. when DNA polymerase activity had not yet increased. Under these experimental conditions, LIF in vivo treatment prevented α DNA polymerase activity from increasing after partial hepatectomy, so that enzyme activity at 24 hr in LIF-treated rats decreased compared to the controls. No direct inhibitory effect of LIF on α DNA polymerase was detected. LIF did not affect β DNA polymerase. These results suggest that LIF plays a part in controlling liver growth.     

THE INDUCTION OF TRANSIENT INCREASES IN MITOTIC RATE IN MURINE TISSUES FOLLOWING PROLONGED INTRAVENOUS INFUSIONS OF HYDROXYUREA

Intravenous infusions of hydroxyurea were established in mice and maintained for periods up to 48 hr. The influence of different rates of hydroxyurea infusion on the number of viable cells gathered in S phase was studied in eight different mouse tissues. An infusion rate which was sufficiently slow not to block thymidine incorporation completely, resulted in gathering of cells in S phase while offering some protection against hydroxyurea-induced cell death. The duration of the period of DNA synthesis following release from hydroxyurea inhibition appeared to be shortened in some tissues. After the release of hydroxyurea blockades maintained for 12–24 hr, each of the tissues showed sharp increases in mitotic activity and peak mitotic index values were as much as twenty times greater than values found in tissues of control animals. An important finding was that the time of maximal mitotic activity for different tissues after release of blockade could differ by many hours.     

A stochastic model for dual label experiments: an analysis of the heterogeneity of S phase duration

We develop a statistical approach for the study of S phase duration in experiments using sequential pulses of two thymidine analogues. Cell entrance into S phase is assumed to follow a possibly nonhomogeneous Poisson process, and the duration in S phase independently follows an unspecified distribution, thus allowing the possibility of variable S phase duration times for cells. Several conclusions regarding experimental design considerations are reached. The availability of three labelled cell subgroups comprising cells receiving exactly one of the two thymidine analogues or receiving both thymidine analogues at least doubles the efficiency of the mean S phase duration estimate compared to conventional estimates based on two labelled groups. Increasing the duration between the two thymidine analogue pulses can also dramatically increase the efficiency. The modelling technique was applied to fourteen uveal melanomas from patients who received in vivo injections of two thymidine analogues, bromodeoxyuridine (BrdUrd) and iododeoxyuridine (IdUrd). Counts of labelled cells were consistent with steady-state time homogeneous entry into S phase and nonhomogeneous spatial entry into S phase.     

CYTOKINETICS OF RAT TRACHEAL EPITHELIUM STIMULATED BY MECHANICAL TRAUMA

Mild abrasion of rat tracheal epithelium results in irreversible damage to the superficial cells and stimulates the viable basal cells to participate in a nearly synchronous wave of DNA synthesis and mitosis. For the growth population as a whole, DNA synthesis started at 14 hr after injury and persisted for 16 hr. The duration of S in individual cells was determined autoradiographically by identifying the time at which a second pulse of DNA precursor (¹⁴C-TdR) was no longer incorporated by cells labelled with ³H-TdR at the onset of S. S was found to be 8–9 hr long. It was also determined that cells entering S at later times synthesized DNA for the same 8–9 hr period. T_G2 was calculated to be 21/2–31/2 hr by subtraction of T_s and 1/2T_M from the period from onset of DNA synthesis to metaphase. By making a second denuding lesion adjacent to the first injury, the cells were stimulated through at least another period of S. At the peak of the second wave of DNA synthesis (50 hr after injury) ¹⁴C-TdR was present in the same cells which had incorporated ³H-TdR administered at the mid-point of the preceding synthetic phase. The 28-hr interval between these two peaks of synthesis is the measure of cell cycle duration for these regenerating tracheal epithelial cells.     

BISACK ANALYSIS OF THE PHYTOHAEMAGGLUTININ-INDUCED PROLIFERATION OF HUMAN PERIPHERAL LYMPHOCYTES

The rate of stimulation as well as subsequent cell cycle duration was examined in phytohaemagglutinin-stimulated human peripheral lymphocytes grown in vitro in the presence of non-inhibitory concentrations of bromodeoxyuridine. After incorporation of this heavy atom analogue of thymidine into replicating cellular DNA, it was possible to identify unequivocally metaphase cells which had replicated for one, two and three or more cell cycles. Utilizing this technique, distribution curves were obtained for the appearance of metaphase cells in successive generations, were analysed by a computer simulation model, and the rate of stimulation (4.5% per hr of the remaining unstimulated population) and cell cycle duration (12·3 hr) were determined. The results were compared with those obtained by autoradiography and the possible relationship to the ‘transition probability’ model for cellular proliferation is discussed.     

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.     

INTERFERENCE OF SEX-RELATED FACTORS IN THE RESPONSE OF LIVER CELLS TO EXPERIMENTAL MITOTIC STIMULI

Stimulation of liver cell multiplication was obtained under two different experimental conditions.

• 1 A single injection of casein solution resulted in (a) an identical synchronized mitotic wave response in 10-day old male and female rats and (b) a significantly lower response in adult male rats compared to females, a difference which was reduced by castration of males at birth but essentially maintained if animals were operated when 10 days old.
• 2 Partial hepatectomy shortly after puberty resulted in active hepatocyte multiplication occurring 3 hr earlier in females than in males. This difference was suppressed when females were ovariectomized at birth and significantly reduced when they were spayed at a later age. Hepatocytes of castrated females entered actively into S phase 2 hr later than the sham-operated controls. Unilateral ovariectomy on the other hand indicated that during compensatory and/or hyper-compensatory activity of the single ovary there was a maximum difference between the male and female rate of [³H]thymidine uptake in liver nuclei 20 hr after hepatectomy. A further kinetic study (t= 25, 30, 40, 65, 90 hr) indicated no significant sex-related difference in the number of S phases per 10,000 cells.

The DNA content of regenerating versus control livers was comparable in both sexes at t= 22 and 90 hr but higher in females at t= 40 and 65 hr. A possible early postnatal interference of certain hormonal mechanisms in the receptivity to mitotic stimuli is postulated and discussed.     

The Circadian Variations In the Eithelial Growth of the Hamster Cheek Pouch: Quantitative Analysis of Dna Distributions*

The pronounced diurnal rhythm in DNA distribution of the hamster check pouch epithelium both in the S fraction and in the (G₂+ M) fraction was compared with previous studies of the changes in tritiated thymidine labelling index and mitotic activity. the DNA distributions were obtained by flow cytometry after ultrasonic disaggregation of the isolated epithelium into a suspension of single nuclei. the DNA distributions were analysed with the computer program of J. Fried (1976) and by planimetry. the S fraction was higher than the autoradiographic labelling index during the whole 24 hr period. Only the computer fitted S fraction and the labelling index had the same difference between maximal and minimal values, and maxima at the same time of day. the DNA distributions showed a diurnal release of G₁ cells into S phase proceeding through (G₂+ M) phase and returning to G₁ phase within a 24 hr period.     

The incorporation of thymidine into deoxyribonucleic acid in mouse fibroblasts infected with polyoma virus

1. Mouse-fibroblast cultures in the stationary phase of growth show an increased rate of [(3)H]thymidine incorporation into DNA from 12 to 44hr. after infection with polyoma virus. 2. Intracellular virus progeny is first detected at about 24hr. after infection. 3. Calculations based on the [(3)H]thymidine-incorporation data and direct measurements of the DNA content of the cell cultures indicate that the amount of the excess of DNA synthesized by the infected cell cultures corresponds to about 10% of their total DNA. 4. The mitotic index of the cell cultures at 40hr. after infection was significantly higher than that of non-infected control cells. 5. Possible interpretations of the stimulation of DNA synthesis observed in polyoma-infected cell cultures are discussed.     

DNA and RNA Syntheses by Intraerythrocytic Stages of Plasmodium knowlesi*

Incorporation of the nucleic acid precursors, orotic acid, adenosine, thymidine, and uridine, was studied in various stages of intraerythrocytic Plasmodium knowlesi from infected rhesus monkeys. Incubation of the parasitized erythrocytes with the precursors was for 3 hr periods using a plasma-free culture medium. The samples containing primarily rings, early trophozoites, or late trophozoites incorporated orotic acid, adenosine, and uridine into RNA; however, these stages exhibited negligible or very low levels of incorporation of any of the precursors into DNA. The sample containing late trophozoite and schizont stages incorporated orotic acid, adenosine, and uridine into RNA, and orotic acid, adenosine, and very low levels of thymidine into DNA. These results indicate that DNA synthesis (the S phase of the cell cycle) occurs very close to the time of nuclear division, and that either the G1 or G2 phase is very short in P. knowlesi. It was also observed that adenosine and orotic acid, 2 precursors which are incorporated into both DNA and RNA, are utilized differently by the intraerythrocytic parasites. Incorporation of orotic acid into RNA and DNA and adenosine incorporation into DNA were continuous for the entire incubation period, whereas incorporation of adenosine into RNA was very low during the last 2 hr of each period. It was further demonstrated that the parasites utilized exogenous uridine for synthesis of RNA, and that the older parasite stages incorporated thymidine into DNA.     

Interferon inhibition of thymidine incorporation into DNA through effects on thymidine transport and uptake

Replenishment of medium after 72 hr of growth of HeLa-S3 cells in dense suspension cultures increased [³H]-thymidine uptake into cells and incorporation into DNA, with the levels reaching a peak ～ 12 hr following medium change; β interferon inhibits the enhanced uptake of [³H]-thymidine and labeling of DNA in a dose-dependent manner. Some reduction in these processes is observed at a concentration as low as 1 u/ml, and ～ 75% inhibition at 640 u/ml. Kinetic analysis has revealed that the rate of labeling of the acid-soluble pool with [³H]-thymidine, measured either at 22°C, or 37°C, is reduced in interferon-treated (640 u/ml, 24 hr) HeLa-S3 cells. At 22°C, the initial rate of thymidine transport at a high (500 μM) thymidine concentration, determined within the first 30 sec of [³H]-thymidine addition was depressed by 44% in interferon-treated HeLa cells. At 37°C, labeled precursors accumulate in acid-soluble material for ～ 8 min after the addition of [³H]-thymidine, after which an apparent equilibrium level is attained. At this temperature, the rate of thymidine uptake and the apparent equilibrium level attained were depressed by 70% in interferon-treated HeLa cells. The reduced incorporation of [³H]-thymidine into DNA in interferon-treated HeLa-S3 cells can be largely explained by interferon inhibition of thymidine transport and phosphorylation.     

A comparative kinetic analysis of proliferation in vitro of Con-A-treated splenocytes and syngeneic leukaemia cells

Abstract. The growth kinetics of Con-A-treated mouse splenocytes and syngeneic leukaemia cells cultured in vitro were compared with respect to (i) the total cell number, (ii) the rate of [¹⁴C]thymidine incorporation (measured by pulse-labelling the cells at various times of incubation), and (iii) the labelling index of the cell populations. By correlating the thymidine incorporation, labelling index and cell number data, it has been established that, for both types of cells, the rate of [¹⁴C]thymidine incorporation is directly proportional to the number of cells synthesizing DNA. A new approach to cytokinetic analysis has been developed, showing that important information can be obtained by determining the cumulative kinetics of [¹⁴C]thymidine incorporation. The latter has been calculated by integrating the area underneath the time course of the rate of thymidine incorporation, and was directly proportional to the overall growth of both leukaemia cells and Con-A-stimulated splenocytes. Based on this proportionality, an estimate of the average duration of the S phase for both types of cells was calculated, suggesting that normal and neoplastic blasts maintain this parameter at a constant value (7.6 and 5.9 hr, respectively) throughout different stages of growth. The percentage of Con-A-responsive cells within the initial splenocyte population and their overall proliferation in vitro have been determined by a procedure which measures the cumulative kinetics of thymidine incorporation and the kinetics of cell total number in the presence or in the absence of the lectin, as well as in the presence of Con-A plus colcemid. A minor fraction (11%) of the initial splenocytes is recruited into cycle by Con-A, proliferating with similar kinetics to that of leukaemia cells in the same conditions. The great majority of the initial splenocyte population is unaffected by Con-A, decaying exponentially throughout the incubation with the same half-life (28 hr), both in the presence or in the absence of the lectin.     

Biogenesis of mammalian mitochondria in the renoprival kidney. II. Aspects of mitochondrial DNA synthesis

Mitochondrial DNA (m-DNA) content and factors which might control its concentration were investigated in the renoprival kidney at various times after unilateral nephrectomy. On the basis of mitochondrial protein, m-DNA increased 30% in the renoprival kidney at 24 hr and returned to normal by 48 hr. The total tissue content of m-DNA was also increased at 24 hr. The specific activity of [³H]thymidine incorporated into m-DNA in vivo was decreased markedly at 24 hr after mononephrectomy; at the same time there was a threefold increase of [³H]thymidine incorporation into total cellular DNA. The incorporation into m-DNA was above normal at 48 hr. The mitochondrial specific DNase was decreased 60% at 24 and 36 hr post-mononephrectomy. There was no significant difference in the total radioactivity or total optical density at 260 nm of the acid soluble extract from mitochondria isolated at various times after mononephrectomy. The incorporation of [³H]thymidine into TMP and TDP in the renoprival kidney was not different from normal but there was a decrease in the incorporation into TTP. It is suggested that the increase in mitochondrial DNA could be due to a decrease in the rate of degradation rather than an increase in synthesis.     

Establishment and Growth Kinetics of the Mutant Ehrlich-Lettré Ascites Cell Strain Hd33 In Permanent Suspension Culture1,2

Cells of a mutant in vivo subline of the Ehrlich-Lettré mouse ascites tumour (ELAT) were converted to growth in suspension culture. Kinetic analysis revealed the selective character of the conversion process; without a detectable adaptation period, a fraction of about 2 × 10^-5 of the explanted cells continued to grow in vitro. the resulting, mutant Ehrlich-Lettré ascites cell strain was designated HD33 and propagated uninterruptedly from 1974 on. the corresponding in vivo ELAT subline HD33 was derived from the HD33 ascites cell strain by intraperitoneal retransplantation. In HD33 cell suspension cultures, the population doubling time, the average intermitotic interval, as determined by videomonitoring, and the average duration of the cell cycle, as determined from percentage of labelled mitoses (PLM) data, were all measured at 15 hr. Cell loss and quiescent compartments were insignificant. the duration of the G₁ phase was effectively zero. Both PLM data and [³H]/[¹⁴C] thymidine double-labetling measurements revealed an S-phase duration of between 11 and 12 hr. the G₂ phase lasted 3–5 hr. The HD33 strain differs from comparable suspension strains of wild-type Ehrlich ascites cells in the insignificant role of density-dependent inhibition in growth, and the striking prolongation of the S phase which is associated with an excessive, cytoplasmic storage of glycogen by the mutant cells.     

The circadian variations in the epithelial growth of the hamster cheek pouch: quantitative analysis of DNA distributions

The pronounced diurnal rhythm in DNA distributions of the hamster cheek pouch epithelium both in the S fraction and in the (G2 + M) fraction was compared with previous studies of the changes in tritiated thymidine labelling index and mitotic activity. The DNA distributions were obtained by flow cytometry after ultrasonic disaggregation of the isolated epithelium into a suspension of single nuclei. The DNA distributions were analysed with the computer program of J. Fried (1976) and by planimetry. The S fraction was higher than the autoradiographic labelling index during the whole 24 hr period. Only the computer fitted S fraction and the labelling index had the same difference between maximal and minimal values, and maxima at the same time of day. The DNA distributions showed a diurnal release of G1 cells into S phase proceeding through (G2 + M) phase and returning to G1 phase within a 24 hr period.