Effects of hydroxyurea on DNA synthesis in hairless mouse epidermis

The effect of 5 mg hydroxyurea (HU) i.p. on epidermal DNA synthesis in female hairless mice was assessed by measuring labelling indices and specific activity after 3HTdR injection, flow cytometry (FCM) and cell sorting of prelabelled basal cells. HU causes an almost immediate block in DNA synthesis lasting until 2-2.5 h. During this time the fraction of cells in S remains stationary, 1.20 of normal. From 2.5 to 12.5 h DNA synthesis is resumed, but in cells recruited from G1 or G0. The HU-blocked cells do not move out of S until after 12.5 h. Hence, from 2.5 to 12.5 h, the fraction of cells in S increases to 2.5 of normal, which means that entry into S is open, but exit is blocked. From 12.5 h flux through S is high. The blocked cells are now released and the fraction of cells in S falls to 0.7 of normal at 24.5 h. At 36.5 h a probable new wave of DNA synthesis is indicated. The results also show that 3HTdR is available for at least 20 min after i.p. injection. The consequences of these results for the interpretation of the effect of HU pretreatment on methylnitrosourea skin carcinogenesis are discussed.     

DNA replication fork progression rate and temporal organization of S phase in normal epidermis and in basal cell carcinoma

The double-pulse labeling technique for DNA fiber autoradiography was applied to epidermal cells from normal human skin and from human basal cell carcinoma (BCC). We aimed to measure the size and replication rate of the replication unit (RU) for both types of cell and to account, from these results, for our previous observation of a near doubling of S-phase duration in BCC, compared with normal skin. The mean RU size was 76 +/- 4 micron in BCC, not significantly different from the 68 +/- 6 micron value found in normal skin, so the mean of those two values (i.e., 72 micron), was used in further calculations. The rate of replication fork progression was 0.59 +/- 0.005 micron/min in the normal epidermis and 0.33 +/- 0.03 micron/min in BCC, corresponding to a replication time of the average RU equal to 61 min and 109 min, respectively. Thus, with an unchanged RU size in BCC, the observed 1.8-fold decrease in the rate of fork progression in the tumor can account entirely for our previous observation of a 1.8-fold increase in S-phase duration in this tumor, without requiring the assumption of any change in the temporal organization of DNA synthesis in the malignant cells. Considering S phase as an ordered process in which a major part, if not all, of the genome replicates at genetically determined times, we suggest that the clusters of replication units are, in turn, organized into temporally defined "sets". These sets are composed of all the clusters (whatever their chromosomal location) that are programmed to initiate replication during the same fraction of the S period. This hypothesis implies that DNA synthesis in a given set is triggered by some event coupled to progression of replication in the immediately preceding set. Based on a S-phase duration of 10.2 hours in normal skin and of 19.2 hours in BCC (our previous data), and assuming perfect synchrony and homogeneity of the clusters within each set and of each cluster's constitutive RUs, the minimum number of sequentially replicating sets, in both instances, can be estimated as roughly equal to 10.     

Changes in the rate of DNA replication fork movement during S phase in mammalian cells.

DNA fiber autoradiography was used to measure the rate of replication fork movement and the size of replication units as a function of time during the S phase of synchronized Chinese hamster ovary cells. The rate of fork movement increased by about threefold from early S to later S phase, with the most dramatic change occurring in the first hour of S phase. On the other hand, the size of replication units did not vary significantly during S phase.     

Subpopulations of slowly cycling cells in S and G2 phase in mouse epidermis

Evidence has been presented supporting the existence of heterogeneity in cell-cycle progression in mouse epidermis, The present study was undertaken to characterize this heterogeneity in more detail. Hairless mice were continuously labelled with tritiated thymidine every 4 hr for 4 days. Basal cell suspensions were prepared from slices of mouse skin at intervals during the experiment and subjected to DNA flow cytometry. Cell-cycle analysis was combined with sorting of cells from windows in G1, S and G2 phase, and the proportion of labelled cells within each window was determined in autoradiographs. Reanalysis and resorting to control the purity of of sorted fractions were performed. Computer simulations of the data were made using a mathematical model assuming different S and G2 phase characteristics. A good fit to the data was only obtained when heterogeneity in mouse epidermal cell-cycle progression was assumed, indicating the existence of slowly traversing, distinct subpopulations of cells in G2 and S phase. These cells are assumed to contribute to about 40% of all cells in S phase and to about 70% of all in G2 phase. The estimated residence times in the resting states were 38 and 32 hr in S and G2 phase, respectively. Two-parameter sorting based on DNA and light scatter indicated that slowly cycling cells were larger than the average. There is no evidence of significant subpopulations of permanently non-proliferating keratinocytes in any of the cell-cycle phases.     

Meiotic DNA synthesis during mouse spermatogenesis

The incorporation of radioactivity into various cells in the sequence of spermatogenesis was measured by preparing highly purified spermatozoan nuclei from the cauda epididymidis of mice at daily intervals after injection of (3H)thymidine. The stages of differentiation of these sperm at the time of thymidine administration were calculated from the kinetics of spermatogenesis. The procedure for purification of sperm nuclei included sonication, mechanical shearing, and treatment with trypsin, DNase, Triton X-100, 2M NaC1, and sodium dodecyl sulfate. DNA was isolated from these nuclei by treatment with dithiothreitol and pronase, followed by phenol extraction and ethanol precipitation. The levels of radioactivity in the epididymal sperm head preparations were low (less than 13 dpm/mouse) for 27 days after injection, and then rose dramatically to over 4 times 104 dpm/mouse. Further experiments demonstrated that the 11 dpm of 3H radioactivity contained in sperm heads at 21 or 26 days after injection of (3H)TdR was significantly above background and contamination levels from other cells or other sources. Most of the radioactivity was in the sperm DNA and represented incorporation of tritium from (3H)TdR into the nuclear DNA of meiotic cells at 0.002 percent of the rate of incorporation into S-phase cells. Little, if any, (3H)TdR was incorporation into the DNA of spermatids. The levels of DNA synthesis during the meiotic prophase in the mouse appear to be much lower than those reported for other organisms.     

DNA strand break rejoining in human lymphocytes during the S phase

Induction and repair of DNA strand breaks in asynchronous and synchronized cultures of human lymphocytes was investigated by using the alkaline DNA-unwinding technique followed by chromatography on hydroxylapatite. Strand break rejoining in exponentially growing human PHA stimulated lymphocytes, irradiated with 20 Gy of X-rays, is temperature-dependent, being fast at 37 degrees C (half-time of a few minutes), and very slow at around 4 degrees C. In synchronized cells irradiated with the same X-ray dose, the repair capacity increases during S phase reaching its maximum when DNA is entirely duplicated.     

Ornithine decarboxylase activity in relation to DNA synthesis in mouse interfollicular epidermis and hair follicles.

The relationship between ornithine decarboxylase (L-ornithine carboxylyase, EC 4.1.1.17) activity and DNA synthetic activity was studied in mouse epidermis. Interfollicular epidermis and hair follicles were investigated separately. It was found that, in hair follicles, the variations of DNA replicative activity, which are reflected in the cyclic growth of hair, are paralleled by corresponding changes in ornithine decarboxylase activity. In both interfollicular epidermis and hair follicles, stimulation of DNA synthetic activity by plucking of hair induced a rapid and marked increase in ornithine decarboxylase activity. The relationship of steady-state and induced ornithine decarboxylase activity to DNA synthetic activity was compared in hair follicles and interfollicular epidermis. A correlation between the activity of this enzyme and DNA replication was found thereby in each of these tissues.     

Influence of DNA synthesis inhibition on the coordinate expression of core human histone genes during S phase

Core histone mRNA metabolism has been examined in S phase HeLa cells recovering from DNA synthesis inhibition by 1 mM hydroxyurea. Using cloned human histone genes as probes for histone mRNA quantitation, the response to and recovery from DNA synthesis inhibition is shown to depend on the position of the cell with respect to the initiation of DNA replication. The incorporation of 3H-uridine into multiple histone mRNAs in recovering cells does not exceed preinhibition levels, and as this incorporation is maximal in early S phase, the synthesis of core histone mRNA is apparently related to the ordered replication of the genome. The total histone mRNA present in interrupted S phase cells after recovery is not significantly different from that present in control cells, and a temporal and functional coupling between histone mRNA levels and the relative rate of DNA synthesis is maintained in perturbed cells.     

DNA synthesis in the mouse blastocyst during the beginning of delayed implantation

The spatiotemporal pattern of DNA synthesis in the mouse embryo at the beginning of metabolic dormancy was examined. Embryos were recovered from females at intervals following ovariectomy at 1100 hours on day 4 of pregnancy, incubated in vitro for 1 h in the presence of [3H]thymidine, and prepared for light microscopic autoradiography. The proportion of labeled cells in the embryo remained high (40-60%) for 18 h after ovariectomy and then declined gradually to 12% by 96 h. However, analysis of individual cell subpopulations showed that the decline was not uniform in all regions of the blastocyst. Labeling was high over the inner cell mass (ICM) during all time intervals in the study, while labeling over the mural trophoblast cells declined sharply by 24 h after ovariectomy. Labeling over the polar trophoblast also declined but had values that were intermediate between the ICM and mural trophoblast regions of the blastocyst. These regional differences in DNA synthesis during the arrest of development suggest that intermediate steps are involved in control of DNA synthesis in the embryo and that the ICM may play a role in the different responses of the trophoblast cell populations.     

Epidermal DNA synthesis in organ culture explants. A study of hairless mouse ear epidermis.

Explants of split mouse ear were incubated in organ culture for up to 48 h, and the cell proliferation was studied by the addition of Thymidine-methyl-3-H (3HTdR) to the medium during different time periods, mainly for the first 14 h of incubation. Cultures were started at 0900, 2130 and 2300. In all cases the labelling index remained stable for 6-8 h, and then increased. The mean grain count, however, was falling and so was the epidermal DNA-specific uptake of 3HTdR. Based on the experimental results, calculations can be made of the flux of cells through S. It is concluded that the increasing LI is not due to inherent diurnal variation in cell proliferation, and is not a sign of real growth but caused instead by a complete block of the cell exit from S, probably combined with periods of an increased entrance rate into S. Other methodological factors, however, may also contribute to the increasing LI. Hence, this system is not suited for the measurement of factors that influence epidermal DNA synthesis.     

Variation in the rate of DNA chain growth through the S phase in HeLa cells

At five to six hours after the beginning of the S phase, the over-all rate of HeLa cell DNA synthesis is about five times as great as in early S cells. This is due both to an increased number of growing points and to a doubling of the average rate of growth along replicons. The pattern of replicon operation in HeLa cells is changed when the “thymidine double-block” method is used to induce synchrony.