Effects of hydroxyurea on the mitotic activity and the G2 phase in hairless mouse epidermis

Hairless mice were given 5 mg hydroxyurea (HU) intraperitoneally (i.p.) followed by 0.15 mg Colcemid at various times after HU. The animals were killed at 2 and 4 hr after Colcemid, the epidermal mitotic counts in dorsal skin were determined and the mitotic rates calculated. These were compared with the normal mitotic rates, and the ratios between the results from HU-treated and -untreated animals were calculated. Hydroxyurea caused a considerable reduction in the mitotic rate with a trough at 6 hr, followed by a wave of increased mitotic rate with a peak at 14 hr, followed by a secondary drop at 20 hr, and then a return to normal. Another group of mice were given HU only, and the fraction of epidermal cells in G2 was measured by flow cytometry. From these animals, without previous injection of Colcemid, we also determined the mitotic counts and calculated the mitotic durations. Cells piled up in G2 for the first 6 hr after HU injection, then the G2 compartment was emptied. The results are discussed in relation to previous results from this department showing the effect of the same dose of HU on DNA synthesis in the same mouse strain. It is concluded that HU not only blocks or retards DNA synthesis in epidermal cells, but also affects the movement of cells through G2 and M. The cell kinetic effects of HU thus seem to be very complex.     

Recovery kinetics of epidermal cell proliferation after two intraperitoneal injections of epidermal extracts (chalone)

The cell kinetic effect of two intraperitoneal (IP) injections of 5 mg of crude lyophilized skin extracts given 12 h apart was assessed during the recovery period (5 to 52 h after last injection) by measuring epidermal labelling indices and the specific activity after tritiated thymidine (3HTdR) injection, and by determining the cell cycle phase distribution by flow cytometry. The skin extracts produced an epidermal chalone effect and inhibited both DNA synthesis and mitosis. A slow recovery took place from 5 to between 22 and 36 h after the last chalone injection. During this period the cell flux into DNA-synthesis and mitosis slowly recovered, but the exits were blocked and cells accumulated in the respective phases. The fluxes out opened up at the S phase about 22 h, and at the M phase about 30 h after the second chalone injection. A secondary inhibitory effect was observed at about 40 h, followed by a subsequent recovery to normal at 52 h. The similarity between the recovery kinetics after chalone and that observed after hydroxyurea (HU) is emphasised.     

Different epidermal cell kinetic effects of hydroxyurea when injected at two different times of the day

Circadian rhythms in epidermal basal cell-cycle progression in hairless mouse skin have been repeatedly demonstrated. A dose of 10 mg/animal hydroxyurea (HU), given to inhibit DNA synthesis was injected intraperitoneally to two groups of hairless mice. One group was injected at 10.00 hours MET, when the cell-cycle progression and cell division rate are relatively high, and another group was injected at 20.00 hours, when the same variables are at minimum values. Various cell kinetic methods--[3H]TdR autoradiography, DNA flow cytometry and the stathmokinetic method (Colcemid)--were used to study HU-induced alterations in cell kinetics. Hydroxyurea (HU) immediately reduced the labelling index (LI) to less than 10% of controls when injected at both times of the day, and higher then normal values were observed 8 hr later. A subsequent decrease towards normal values was steeper in the 20.00 hours injected group. The proportion of cells with S-phase DNA content was transiently reduced in both series, but the reduction was less pronounced and control values were reached earlier in the series injected at 10.00 hours. The observed alterations in LI and fraction of cells in S phase were followed by comparable alterations in the fraction of cells in G2 and in the mitotic rate. Hence the changes in G2 and mitotic rate are easily explained as consequences of the previous perturbations in the S phase. The time-dependent differences in the cell kinetic perturbations caused by HU in the S phase may be explained by a circadian-phase-dependent action of HU on the influx and efflux of cells to and from the S phase, respectively. At 10.00 hours the efflux of cells from S is most heavily inhibited; at 20.00 hours the influx is predominantly blocked. Hence, when physiological flux is high HU mainly blocks the efflux from S, but when flux normally is low, HU mainly blocks the entrance to S. Within 20 hours after the HU injection, the cell kinetic variables had approached the unperturbed circadian pattern.     

An in vivo study on the synchronizing effect of hydroxyurea

The effect of hydroxyurea (HU; 0.5 mg/g body wt) on L 1210 ascites tumor cells has been studied using various cell kinetic methods. In contrast to the general assumption that HU blocks cells at the G1/S boundary [J. Brachet (1985) Molecular Cytology, Vol. I, p. 266, Academic Press, New York], the present results show that the cells are not held at G1/S but enter S at about the normal rate and are accumulated in early S phase due to a dose-dependent inhibiting effect of HU on DNA synthesis. Partial synchronization of the cells demonstrated by a distinct mitotic peak 10 h after HU application is not due to a G1/S block of the cells and their subsequent synchronous passage through the cycle after release from the block but is due to rather complex mechanisms of action of HU: a differential cytocidal effect and an effect on the passage of the cells through the cycle, both depending on the position of the cells throughout the cycle. HU kills S-phase cells, mainly cells in early S phase; i.e., a great portion of the cells "accumulated" in early S phase is killed by the drug, while G1-phase cells are almost not affected by the lethal effect of HU. These G1-phase cells pass through the cycle more rapidly after cessation of the HU effect. The same is true for the surviving cells accumulated in early S phase, while part of the cells in the remaining S phase are delayed in their passage through the cycle. This causes partial synchronization, since a great portion of all cells that survive HU treatment reach mitosis at the same time.     

Effects of Hydroxyurea On the Mitotic Activity and the G2 Phase In Hairless Mouse Epidermis

Hairless mice were given 5 mg hydroxyurea (HU) intraperitoneally (i.p.) followed by 0.15 mg Colcemid® at various times after HU. the animals were killed at 2 and 4 hr after Colcemid, the epidermal mitotic counts in dorsal skin were determined and the mitotic rates calculated. These were compared with the normal mitotic rates, and the ratios between the results from HU-treated and -untreated animals were calculated. Hydroxyurea caused a considerable reduction in the mitotic rate with a trough at 6 hr, followed by a wave of increased mitotic rate with a peak at 14 hr, followed by a secondary drop at 20 hr, and then a return to normal. Another group of mice were given HU only, and the fraction of epidermal cells in G₂ was measured by flow cytometry. From these animals, without previous injection of Colcemid, we also determined the mitotic counts and calculated the mitotic durations. Cells piled up in G₂ for the first 6 hr after HU injection, then the G₂ compartment was emptied. the results are discussed in relation to previous results from this department showing the effect of the same dose of HU on DNA synthesis in the same mouse strain. It is concluded that HU not only blocks or retards DNA synthesis in epidermal cells, but also affects the movement of cells through G₂ and M. the cell kinetic effects of HU thus seem to be very complex.     

Subdivision of the G1 phase of human glia cells in culture

Human glia cells blocked post-mitotically by serum deprivation require about 8–12 h of continuous stimulation by growth factors to become committed to DNA synthesis. DNA synthesis begins about 5 h after growth factor withdrawal. The length of time until the S phase began and the length of the apparent commitment period, i.e. the time when cells progressed towards the G1/S transition point even in the absence of growth factors were independent of the nature of the growth factors studied (calf serum, platelet-rich human serum, epidermal growth factor). Epidermal growth factor and calf serum were mutually interchangeable during the pre-commitment period. Increasing cell density reduced the number of cells which entered DNA synthesis, but had no effect on the length of the apparent commitment period or the latent time until DNA synthesis commenced. The requirement for a long exposure to a growth factor may be an important safeguard in normal cells against “accidental” entry into the cell cycle, since malignant glia cells do not show the same requirement.     

Hydroxyurea synchoronization of bovine fetal spleen cells.

Hydroxyurea (HU) was shown to be an effective synchronization agent for bovine fetal spleen (BFS) cells. Following exposure of cells to 2 mM HU for 32 h, DNA synthesis above background levels was not observed. BFS cells released from the HU block by washing began to synthesize DNA immediately. Within 2 h, 80–85% of the cells were in S phase, as determined by autoradiography, and the maximum rate of DNA synthesis occurred 2–4 h following removal of HU. The rapid induction of DNA synthesis in BFS cells and the high percentage of cells synthesizing DNA immediately after removal of HU demonstrate that HU produces a highly synchronized population of S phase BFS cells. Although RNA and protein synthesis were maintained at near normal rates early after cells were exposed to HU, the rates decreased to 40–50% of those observed in cells seeded in medium without HU by the time of release. These reduced rates of synthesis of RNA and protein in the absence of DNA synthesis may account for the low toxicity of HU for BFS cells.     

Hydroxyurea synchronization of bovine fetal spleen cells

Hydroxyurea (HU) was shown to be an effective synchronization agent for bovine fetal spleen (BFS) cells. Following exposure of cells to 2 mM HU for 32 h, DNA synthesis above background levels was not observed. BFS cells released from the HU block by washing began to synthesize DNA immediately. Within 2 h, 80–85% of the cells were in S phase, as determined by autoradiography, and the maximum rate of DNA synthesis occurred 2–4 h following removal of HU. The rapid induction of DNA synthesis in BFS cells and the high percentage of cells synthesizing DNA immediately after removal of HU demonstrate that HU produces a highly synchronized population of S phase BFS cells. Although RNA and protein synthesis were maintained at near normal rates early after cells were exposed to HU, the rates decreased to 40–50% of those observed in cells seeded in medium without HU by the time of release. These reduced rates of synthesis of RNA and protein in the absence of DNA synthesis may account for the low toxicity of HU for BFS cells.     

The adenovirus E1A protein overrides the requirement for cellular ras in initiating DNA synthesis.

The adenovirus E1A protein can induce cellular DNA synthesis in growth-arrested cells by interacting with the cellular protein p300 or pRb. In addition, serum- and growth factor-dependent cells require ras activity to initiate DNA synthesis and recently we have shown that Balb/c 3T3 cells can be blocked in either early or late G1 following microinjection of an anti-ras antibody. In this study, the E1A 243 amino acid protein is shown through microinjection not only to shorten the G0 to S phase interval but, what is more important, to override the inhibitory effects exerted by the anti-ras antibody in either early or late G1. Specifically, whether E1A is co-injected with anti-ras into quiescent cells or injected 18 h following a separate injection of anti-ras after serum stimulation, it efficiently induces cellular DNA synthesis in cells that would otherwise be blocked in G0/G1. Moreover, injection of a mutant form of E1A that can no longer associate with p300 is just as efficient as wild-type E1A in stimulating DNA synthesis in cells whose ras activity has been neutralized by anti-ras. The results presented here show that E1A is capable of overriding the requirement of cellular ras activity in promoting the entry of cells into S phase. Moreover, the results suggest the possibility that pRb and/or pRb-related proteins may function in a ras-dependent pathway that enables E1A to achieve this activity.     

Kinetics of the nuclear division cycle of Aspergillus nidulans.

We have analyzed the cell cycle kinetics of Aspergillus nidulans by using the DNA synthesis inhibitor hydroxyurea (HU) and a temperature-sensitive cell cycle mutant nimT that blocks in G2. HU rapidly inhibits DNA synthesis (S), and as a consequence progression beyond S to mitosis (M) is blocked. Upon removal of HU the inhibition is rapidly reversible. Conidia (asexual spores) of nimT were germinated at restrictive temperature to synchronize germlings in G2 and then downshifted to permissive temperature in the presence of HU. This procedure synchronizes the germlings at the beginning of S in the second cell cycle after spore germination. We have measured the total duration of S, G2, and M as the time required for these cells to recover from the HU block and undergo the next nuclear division. The duration of S was defined by the time course of sensitivity to reintroduction of HU during recovery from the initial HU block. The cell cycle time was measured as the nuclear doubling time, and the duration of mitosis was determined from the mitotic index. The duration of G1 was calculated by subtracting the combined durations of S, G2, and M from the nuclear doubling time, and the length of G2 was calculated by subtracting S and M from the aggregate length of S, G2, and M. We have also determined the duration of the phases of the cell cycle during the first cycle after spore germination. In these experiments spores were germinated directly in HU without first being blocked in G2. Because the durations of G1, S, G2, and M for the first cell cycle after spore germination were identical with those previously determined for spores presynchronized at the beginning of S in the second cell cycle, we conclude that dormant conidia of A. nidulans are arrested at, or before, the start of S.     

Different Epidermal Cell Kinetic Effects of Hydroxyurea When Injected At Two Different Times of the Day

Circadian rhythms in epidermal basal cell-cycle progression in hairless mouse skin have been repeatedly demonstrated. A dose of 10 mg/animal hydroxyurea (HU), given to inhibit DNA synthesis was injected intraperitoneally to two groups of hairless mice. One group was injected at 10.00 hours MET, when the cell-cycle progression and cell division rate are relatively high, and another group was injected at 20.00 hours, when the same variables are at minimum values. Various cell kinetic methods—[³H]TdR autoradiography, DNA flow cytometry and the stathmokinetic method (Colcemid)—were used to study HU-induced alterations in cell kinetics. Hydroxyurea (HU) immediately reduced the labelling index (LI) to less than 10% of controls when injected at both times of the day, and higher then normal values were observed 8 hr later. A subsequent decrease towards normal values was steeper in the 20.00 hours injected group. the proportion of cells with S-phase DNA content was transiently reduced in both series, but the reduction was less pronounced and control values were reached earlier in the series injected at 10.00 hours. the observed alterations in LI and fraction of cells in S phase were followed by comparable alterations in the fraction of cells in G₂ and in the mitotic rate. Hence the changes in G₂ and mitotic rate are easily explained as consequences of the previous perturbations in the S phase. The time-dependent differences in the cell kinetic perturbations caused by HU in the S phase may be explained by a circadian-phase-dependent action of HU on the influx and efflux of cells to and from the S phase, respectively. At 10.00 hours the efflux of cells from S is most heavily inhibited; at 20.00 hours the influx is predominantly blocked. Hence, when physiological flux is high HU mainly blocks the efflux from S, but when flux normally is low, HU mainly blocks the entrance to S. Within 20 hours after the HU injection, the cell kinetic variables had approached the unperturbed circadian pattern.     

Hydroxyurea arrests DNA replication by a mechanism that preserves basal dNTP pools

The relationship between dNTP levels and DNA synthesis was investigated using alpha factor-synchronized yeast treated with the ribonucleotide reductase inhibitor hydroxyurea (HU). Although HU blocked DNA synthesis and prevented the dNTP pool expansion that normally occurs at G1/S, it did not exhaust the levels of any of the four dNTPs, which dropped to about 80% of G1 levels. When dbf4 yeast that are ts for replication initiation were allowed to preaccumulate dNTPs at 37 degrees C before being released to 25 degrees C in the presence of HU, they synthesized 0.3 genome equivalents of DNA and then arrested as dNTPs approached sub-G1 levels. Accumulation of dNTPs at G1/S was not a prerequisite for replication initiation, since dbf4 cells incubated in HU at 25 degrees C were able to replicate when subsequently switched to 37 degrees C in the absence of HU. The replication arrest mechanism was not dependent on the Mec1/Rad53 pathway, since checkpoint-deficient rad53 cells also failed to exhaust basal dNTPs when incubated in HU. The persistence of basal dNTP levels in HU-arrested cells and partial bypass of the arrest in cells that had preaccumulated dNTPs suggest that cells have a mechanism for arresting DNA chain elongation when dNTP levels are not maintained above a critical threshold.     

HYDROXYUREA EFFECTS IN THE C3H MOUSE: I. DUODENAL CRYPT CELL KINETICS

Duodenal crypt cell kinetics in C3H mice have been studied before and after the injection of a single dose (3 mg/g body weight) of hydroxyurea (HU). This was done by autoradiographic analysis of crypt cells which had been labeled with tritiated 5-iodo-2'-deoxyuridine. This dose of HU kills the cells which are synthesizing DNA at the time of injection, inhibits DNA synthesis completely for 4–5 hr, and causes a partial synchronization of the cells when they recover from the inhibitory effects of HU. Duodenal crypt recovery is manifested by a decrease in the mean cell cycle time, an increase in the proliferating fraction, and a lengthening of the crypts. The acute cellular responses are apparently complete within 24–48 hr, but the length of the crypt has not returned to normal by 48 hr after HU administration.     

Different proliferative responsiveness of fibroblasts and mesothelial cells in the rat mesentery following administration of compound 48/80 at various hours of the day.

The proliferative responsiveness of fibrolasts and mesothelial cells in the mesenterial membrane of normal rats was studied quantitatively after a single i.p. injection of the mast-cell activating and histamine-releasing drug Compound 48/80. To make some allowance for a possible chronobiologic effect of the circadian type on the induced proliferation, the drug was given at 1 a.m., 9 a.m., or 5 p.m., and the animals were examined 16, 24, and 32 h later. The proliferation was estimated by cytophotometric Feulgen DNA measurements in individual fibroblast and mesothelial cell nuclei, and by mitotic frequency counting. The main result was that a larger fraction of fibroblasts than of mesothelial cells was stimulated to proliferation, regardless of the hour of treatment with Compound 48/80. It was further demonstrated that in control animals the fraction of cells of either fibroblastic or mesothelial type present in the S cum G2 cell-cycle phases varied markedly at different hours of the day. Quantitative differences appeared in the induced proliferation with regard to the hour of treatment. The most vigorous proliferative response appeared after administration of the drug at 9 a.m. The fraction of cells in the S cum G2 cell-cycle phases was then increased at 16 h and the fraction of dividing cells at 24 h after treatment, illustrating the promptness of the induced proliferative reaction.     

Analysis of the interphase accumulation induced by hydroxyurea on proliferating plant cells.

Cell distribution in different compartments of the cell cycle (G1, early, middle and late S, G2 and mitosis) has been studied during continuous treatments with hydroxyurea (HU) in onion root meristems by cytophotometric and autoradiographic methods. A sublethal dosis of HU (0.75 mM) has been chosen to allow a good wave of mitotic synchrony during recovery, with a negligible level of chromosomal aberrations. Proliferating cells begin the S period in the presence of HU and are accumulated in early S, where the maximum value (60%) is reached after 8 h of treatment; at the same time middle and late S are practically empty. In the presence of the drug, residual DNA synthesis allows a slow but continuous progress of cells throughout the S period. Differential sensitivity of S cells to HU can be observed; replication is more affected in early S (85% inhibition) than in the second half of the period (70% inhibition). On the other hand, G1 cells are not apparently affected by HU, while cells in G2 show a delay in their entrance into mitosis.     

Cell kinetics-dependent antitumor effect of irinotecan hydrochloride induced by the synchronizing effect of hydroxyurea: cell kinetics and dosing time

Influence of hydroxyurea (HU) on the antitumor effect of irinotecan hydrochloride (CPT-11) was investigated in ICR male mice transplanted with sarcoma 180 cells (S-180). A single dose of CPT-11 (100 mg/kg) was injected at various times after a single dose of HU (300 mg/kg). The relative tumor weight varied significantly depending on the timing of CPT-11 injection after HU injection (P < 0.01). The higher antitumor effect of CPT-11 was observed when DNA synthesis of S-180 cells increased (20 hr), and the lower effect was observed when the DNA synthesis decreased (0 hr). The loss of body weight also varied significantly depending on the timing of CPT-11 injection after HU injection (P < 0.01). The toxicity of CPT-11 was higher when the inhibitory effect of HU on DNA synthesis of bone marrow cells was stronger (15 hr), and the lower toxicity was observed when the inhibitory effect was not observed (0 hr). The plasma SN-38 concentration at 2 hr after CPT-11 injection was higher at 20 hr after HU injection than at 0 hr after HU injection. The difference in plasma esterase activity between 0 hr and 20 hr after HU injection was regarded as the mechanism underlying the dosing time-dependent difference of the SN-38 concentration. These experiments suggest that HU can produce a different phase of cell cycle between tumor cells and normal cells. This leads to increase the antitumor effect of CPT-11 without increasing the adverse effect of the drug. It is essential to consider the dosing time in the two-drug combination therapy.     

Deoxyribonucleoside triphosphate metabolism and the mammalian cell cycle. Effects of hydroxyurea on mutant and wild-type mouse S49 T-lymphoma cells

DNA precursor synthesis can be blocked specifically by the drug hydroxyurea (HU) which has therefore been used for anticancer therapy. High concentrations of HU, however, affect other processes than DNA synthesis; nevertheless, most studies on the biological action of HU have been made with concentrations at least one order of magnitude higher than those needed for cell-growth inhibition. In this study we characterized the effects of low concentrations of HU (i.e. concentrations leading to 50% inhibition of cell growth in 72 h) on cell cycle kinetics and nucleotide pools in mouse S49 cells with various defined alterations in DNA precursor synthesis. The effect of 50 microM HU on deoxyribonucleoside triphosphate pools was a 2-3-fold decrease in the dATP and dGTP pools, with no change in the dCTP pool and a certain increase in the dTTP pool. Addition of deoxycytidine or thymidine led to a partial reversal of the growth inhibition and cell-cycle perturbation caused by HU, and was accompanied by an increased level of the deoxyribonucleoside triphosphates. Addition of purine deoxyribonucleoside gave no protection, indicating that salvage of these nucleosides could not supply precursors for DNA synthesis in T-lymphoma cells. We observed a higher sensitivity to HU of cells lacking purine nucleoside phosphorylase or with a ribonucleotide reductase with altered allosteric regulation. Cells lacking thymidine kinase or deoxycytidine kinase were just as sensitive as wild-type cells.     

Cell cycle dependency of murine cytomegalovirus replication in synchronized 3T3 cells.

Synchronized murine 3T3 cells have been used to investigate the possible dependency of murine cytomegalovirus replication upon the cell cycle. The normal latent period of 12 h characteristic of asynchronous 3T3 cells was protracted to more than 24 h after an early G1 infection in synchronous cells. In this case viral progeny were not detected until after the initiation of the host S-phase. Cells maintained in the G1 phase did not replicate virus. This failure could not be explained by a decrease in virus penetration but was apparently due to a requirement for an event associated with the host S-phase. Thymidine-induced inhibition of cell cycle traverse also blocked virus replication. Viral DNA synthesis did not initiate until after the initiation of host DNA. In contrast, herpes simplex virus type 1 replicated in 3T3 cells independently of the cell cycle.     

Changes in cell-cycle duration and growth fraction in the shoot meristem of Sinapis during floral transition

The cell-cycle duration and the growth fraction were estimated in the shoot meristem of Sinapis alba L. during the transition from the vegetative to the floral condition. Compared with the vegetative meristem, the cell-cycle length was reduced from 86 to 32 h and the growth fraction, i.e. the proportion of rapidly cycling cells, was increased from 30–40% to 50–60%. These changes were detectable as early as 30 h after the start of the single inductive long day. The faster cell cycle in the evoked meristem was achieved by a shortening of the G1 (pre-DNA synthesis), S (DNA synthesis) and G2 (post-DNA synthesis) phases of the cycle. In both vegetative and evoked meristems, both-the central and peripheral zones were mosaics of rapidly cycling and non-cycling cells, but the growth fraction was always higher in the peripheral zone.Abbreviations G1 pre-DNA synthesis phase - G2 post-DNA synthesis phase - GF growth fraction - M mitosis phase - PLM percentage-labelled-mitoses method - S DNA synthesis phase - TdR thymidine     

Effects of DNA replication inhibitors on UV excision repair in synchronised human cells.

When HeLa cells are irradiated with UV and treated with the DNA synthesis inhibitors hydroxyurea (HU) and 1-beta-D-arabinofuranosylcytosine (ara C), DNA strand breaks accumulate at sites where excision repair of DNA damage has been inhibited after the incision step. This break accumulation occurs in mitotic, G1 and S phase cells. But UV-induced repair synthesis of DNA, as measured by [3H]thymidine incorporation into unreplicated DNA, is not inhibited by HU and ara C in G1 or S phase cells, even though replicative synthesis is virtually abolished. Repair and replication must therefore utilise different DNA precursor pools, or different DNA synthetic systems; and the action of Hu and ara C in causing strand break accumulation may occur at the ligation step of excision repair.