Urethane inhibition of DNA synthesis in the hepatocytes of the regenerating liver in mice

Hepatocarcinogen urethane (ethyl carbamate) inhibits DNA synthesis in the regenerating mice liver when administered at the peak of stimulated proliferation--46 hours after partial hepatectomy. The inhibition is temporary and reversible. The maximum inhibition of 3H-thymidine incorporation in the cells is observed 12 hours after urethane administration, and the effect is removed following 20 hours after administration. Another effect of urethane consists in the lengthening of the period of DNA synthesis by 1.38 times, as estimated by the Quastler-Sherman method, though it does not affect the length of G2-period or mitosis. Possible mechanisms of the effect of urethane on the initiation of DNA synthesis and on the rate of DNA replication are discussed.     

Structure of the centriolar complex in the hepatocytes of intact and regenerating mouse live

The structure of the cellular center in polyploid hepatocytes of intact and regenerating liver of adult mice has been studied. It was shown that the structure of the centriolar complex depends on stages of the cellular cycle. No pericentriolar structures (such as satellites, appendages and others) and cytoplasmic microtubules were found in the centriolar complex within G0-period. The satellites and appendages are formed in the half of the centrioles within G1-period. The microtubules can branch off some satellites; the daughter centrioles begin to form within S-period; there are diplosomes in the cells within G2-period, some mother centrioles are surrounded with the fine fibrillar halo. It is concluded that the structure of the centriolar complex within G0-period is distinguished by that within G1-period. The structure of the centriolar complex in polyploid hepatocytes has the same feature of reorganization in certain interphase periods of the cell cycle as in diploid cells of some cultured cells and the thyroid epithelium.     

Changes in the chondriome during the cell cycle of a tissue culture of embryonic pig kidney

The regular cyclic changes of number, size, shape and ultrastructure of cells mitochondria during G1, S, G2-periods and mitosis have been shown by morphometric methods on nonsynchronized culture of PEK tissue. Number of mitochondria is equal in G1 and S cells. Middle size and unbranched mitochondria prevail in G1-period, middle size and large organellae of complicated shape are characteristic for S-period. In G2-period number of mitochondria increases in 1,5 times. Simultaneously the portion of middle and small unbranched mitochondria increases and number of large organellae of complicated shape decreases. Number of mitochondria in mitotic cells in comparison with cells of G2-period does not change distinctly. Most mitochondria are middle and small size, usually unbranched in this period. Considerable increase of mitochondria number in G2-period is probably due to division of the branched mitochondria characteristic for the previous S-period. The mitochondria ultrastructure does not undergo marked changes during the interphase of the cell-cycle and characterizes by prevailing of the orthodox forms of mitochondria: in late G2-period and in the process of mitosis the most mitochondria become condensed.     

C- and Q-chromatin of the experimentally condensed human interphase chromosomes]

Condensed interphase chromosomes of the cultured human lymphocytes obtained by the fusion of interphase and metaphase cells were studied using C- and Q-bands techniques. The appearance and localization of the constitutive heterochromatin blocks on condensed chromosomes at G1-period were the same as on the metaphase ones. These characters were used for a group and individual identification of some chromosomes condensed at G1-period and for a study of the association of the constitutive heterochromatin blocks in the interphase nuclei. The fluorescent analysis of the chromosomes condensed at G1-period detected some bright fluorescent blocks of the constitutive heterochromatin.     

Der Zellzyklus in Fibroblastenkulturen vom Menschen

Summary Autoradiography using H³-Thymidin and Feulgen photometry of nuclear DNA-content were carried out on human euploid fibroblast cultures.The average durations of S- and G2-periods are about 9 hours and 5 hours respectively, with only minor variation. The duration of G1-period may vary from a few hours to more than 20 hours.A combined study of H³-thymidin uptake and Feulgen photometry on the same cell nuclei showed that all cells whose DNA-content places them into the S-period are labelled when they are fixed immediate after a H³-thymidin puls. After continuous H³-thymidin uptake for 5 hours, all S- and G2-nuclei are labelled, whereas the G1-nuclei remain unlabelled.The Feulgen histogramm as well as grain counts over labelled nuclei indicate a constant rate of DNA synthesis during S-period.     

Structure of the centriole complex in mouse hepatocytes in the experimental induction of a G2 block

In the regenerating liver hepatocytes the centriolar cycle is retarded corresponding to the delay of the nuclear cycle up to the beginning of G2-block. A prolonged staying of cells in the premitotic condition results in the phenomenon that according to their DNA these cells correspond to the G2-period, whereas according to their centriolar complex structure they move into the following G1 and G0-periods, passing mitosis. Thus, in the G2-blocked hepatocytes there is a separation of the nuclear cycle and centriolar cycles. Moreover, during the diping action the centriolar capacity of forming cytoplasmic and mitotic microtubules is suppressed.     

Cytophotometric determination of unscheduled DNA synthesis

We describe a cytophotometric assay for unscheduled DNA synthesis (UDS) in asynchronously growing cells. Monolayer cultures of human HEp-2 and mouse MCa-11 cells were incubated with the carcinogen methyl-methane sulfonate (MMS), as well as with hydroxyurea and (3H)thymidine. Slides were prepared, and the DNA contents and areas of nuclei were measured by absorption cytophotometry. The labeling of the nuclei, determined on the basis of their DNA content to be in G0/G1, was selectively measured after the preparation of autoradiographs. The labeling of the G0/G1 cells increased with increasing doses of MMS. We also found that the increased nuclear labeling after MMS treatment was not due to induction of replicative DNA synthesis or selective destruction of G0/G1 cells. The results of this assay compared favorably with a standard biochemical method for measuring unscheduled DNA synthesis by benzoylated naphthoylated DEAE cellulose chromatography.     

G1 block of the cell cycle during differentiation of F9 cells correlates with accumulation of inhibitors of the activity of cyclin-kinase complexes of proteins p21/Waf1 and p27/Kip

F9 teratocarcinoma cells have a very short duration of the cell cycle with a short G1-period typical for early embryonic cells. The cells are capable of differentiating towards parietal endoderm cells after the treatment with retinoic acid (RA) and dibutyryl-cAMP (db-cAMP). This leads to changes in the cell cycle; in particular, G1-period becomes longer, and then differentiated F9 cells leave the cycle to stay in G0-phase. It was previously reported that undifferentiated F9 cells undergo no G1 arrest of the cell cycle after DNA damage (Malashicheva et al., 2000). In the present work mechanisms of accumulation of G1-phase cells during differentiation induced by retinoic acid and db-cAMP were studied. Kinase activity of cyclin-Cdk complexes regulating the G1/S transition was analyzed. In differentiated F9 cells, the activity of cyclin-Cdk complexes, comprising Cdk4 and Cdk2 kinases and cyclins A and E, was significantly decreased. A decrease of Cdk4 kinase activity correlates with a drop of the cyclin D1 content. The amount of p21/Waf1 and p27/Kip inhibitors of the cyclin-kinase complexes increased in differentiated F9 cells. p21/Waf1 protein, which undergoes proteasomal degradation in undifferentiated F9 cells, was shown to be stable in their differentiated derivatives. Besides, in differentiated F9 cells p21/Waf1 and p27/Kip proteins can be detected with Cdk4/Cdk2-cyclin E complexes, in contrast to undifferentiated cells. Thus, we suggest that a G1/G0 block of the cell cycle taking place upon differentiation of F9 cells is likely to be caused by a decrease in cyclin-kinase activity due to stabilization and accumulation of p21/Waf1 and p27/Kip inhibitors and to their ability to associate with Cdk-cyclin complexes.     

Cyclic x-ray responses in Mammalian cells in vitro

Various radiation responses in mammalian cells depend on the position of the cell within its generation cycle (that is, its age) at the time of irradiation. Studies have most often been made by irradiating synchronized populations of cells in vitro. Results in different cell lines are not easy to compare, but an attempt has been made here to point out similarities and differences with regard to cell killing and division delay. In general, survival data obtained so far show that, in cells with a short G(1), cells are most sensitive in mitosis and in G(2), less sensitive in G(1), and least sensitive during the latter part of the S period. In cells with a long G(1), in addition to the above, there is usually a resistant phase early in G(1) followed by a sensitive stage near its end. (The latter may be as sensitive as mitosis.) Exceptions to the above, especially in some L cell sublines, have been noted, and a possible explanation is given. In Chinese hamster cells, maximum survival after irradiation occurs during S, but it does not coincide with the time of the maximum rate of DNA synthesis or with the time of the maximum number of cells in DNA synthesis, and changes in survival also occur in cells inhibited from synthesizing DNA. Rather, survival depends on the position the cell has reached in the cycle at that time, which involves not only DNA synthesis but other processes as well. Survival is not completely correlated with DNA synthesis, since halting DNA synthesis just before or just after irradiation only slightly affects survival at its maximum. Division delay exhibits a pattern of response which is similar in most cell lines. Delay is considerable for cells irradiated in mitosis, is small for cells in G(1), increases to a maximum for cells during S, and declines for cells in G(2). L cells or human kidney cells may have a longer delay for cells irradiated in G(2) than for those irradiated in S. The results can be explained in terms of a two-component model of division delay. One component results from the prolongation of the S period due to the reduced rate of DNA synthesis, and the other, a block in G(2), is independent of DNA synthesis. The proportion of the two components may vary in different cell lines.     

Differential response of cycling and noncycling cells to inducers of DNA synthesis and mitosis

The objective of this study was to determine whether cells in G(0) phase are functionally distinct from those in G(1) with regard to their ability to respond to the inducers of DNA synthesis and to retard the cell cycle traverse of the G(2) component after fusion. Synchronized populations of HeLa cells in G(1) and human diploid fibroblasts in G(1) and G(0) phases were separately fused using UV-inactivated Sendai virus with HeLa cells prelabeled with [(3)H]ThdR and synchronized in S or G(2) phases. The kinetics of initiation of DNA synthesis in the nuclei of G(0) and G(1) cells residing in G(0)/S and G(1)/S dikaryons, respectively, were studied as a function of time after fusion. In the G(0)/G(2) and G(1)/G(2) fusions, the rate of entry into mitosis of the heterophasic binucleate cells was monitored in the presence of Colcemid. The effects of protein synthesis inhibition in the G(1) cells, and the UV irradiation of G(0) cells before fusion, on the rate of entry of the G(2) component into mitosis were also studied. The results of this study indicate that DNA synthesis can be induced in G(0)nuclei after fusion between G(0)- and S-phase cells, but G(0) nuclei are much slower than G(1) nuclei in responding to the inducers of DNA synthesis because the chromatin of G(0) cells is more condensed than it is in G(1) cells. A more interesting observation resulting from this study is that G(0) cells is more condensed than it is in G(1) cells. A more interesting observation resulting from this study is that G(0) cells differ from G(1) cells with regard to their effects on the cell cycle progression of the G(2) nucleus into mitosis. This difference between G(0) and G(1) cells appears to depend on certain factors, probably nonhistone proteins, present in G(1) cells but absent in G(0) cells. These factors can be induced in G(0) cells by UV irradiation and inhibited in G(1) cells by cycloheximide treatment.     

Initiation of DNA synthesis in the prematurely condensed chromosomes of G1 cells

The objective of this study was to investigate whether G1 cells could enter S phase after premature chromosome condensation resulting from fusion with mitotic cells. HeLa cell synchronized in early G1, mid-G1, late G1, and G2 and human diploid fibroblasts synchronized in G0 and G1 phases were separately fused by use of UV-inactivated Sendai virus with mitotic HeLa cells. After cell fusion and premature chromosome condensation, the fused cells were incubated in culture medium containing Colcemid (0.05 micrograms/ml) and [3H]thymidine ([3H]ThdR) (0.5 microCi/ml; sp act, 6.7 Ci/mM). At 0, 2, 4, and 6 h after fusion, cell samples were taken to determine the initation of DNA synthesis in the prematurely condensed chromosomes (PCC) on the basis of their morphology and labeling index. The results of this study indicate that PCC from G0, G1, and G2 cells reach the maximum degree of compaction or condensation at 2 h after PCC induction. In addition, the G1-PCC from normal and transformed cells initiated DNA synthesis, as indicated by their "pulverized" appearance and incorporation of [3H]ThdR. Further, the initiation of DNA synthesis in G1-PCC occurred significantly earlier than in the mononucleate G1 cells. Neither pulverization nor incorporation of label was observed in the PCC of G0 and G2 cells. These findings suggest that chromosome decondensation, although not controlling the timing of a cell's entry into S phase, is an important step for the initiation of DNA synthesis. These data also suggest that the entry of a S phase may be regulated by cell cycle phase-specific changes in the permeability of the nuclear envelope to the inducers of DNA synthesis present in the cytoplasm.     

Non-histone protein synthesis during G1 phase and its relation to DNA replication.

The kinetics of non-histone chromosomal protein (NHCP) synthesis were studied in Chinese hamster ovary (CHO) plateau phase cells stimulated to proliferate and were compared to NHCP synthesis kinetics in two populations of synchronous G1 traversing cells. In all cases, NHCP synthesis rates increase 3- to 5-fold as cells traversed G1 and attained maximum values one hour before semi-conservative DNA replication began. Similar to results in synchronous G1 cells, the molecular weight distributions of the NHCP fraction from stimulated plateau phase cells underwent only minor changes, measured by sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis, as these cells moved toward S phase. Yet, during this progression after plateau phase and in the transition from early G1 to late G1 in synchronous cells, the total NHCP fraction increased significantly (1.5-2-fold) in amount per cell. These data indicate that plateau phase cells are similar to early G1 cells both in terms of their amounts of non-histone per cell and in their subsequent NHCP synthesis kinetics as they move toward S phase. These results extend previous findings which suggested that NHCP synthesis was coupled to DNA replication and demonstrate that the increased NHCP synthesis and accumulation in chromatin may be a biochemical marker for G1 progression.     

Differences in the response of early and mid or late G1 WI38 cells treated with cyclohexamide to HeLa inducers of DNA synthesis

The inducibility of DNA synthesis after treatment with cyclohexamide (CHM) during mitosis and the G1 phase of WI38 cells has been studied in the heterokaryons following fusion with HeLa cells in S phase. Synchronized mitotic cells treated for up to 5 h with CHM were not delayed in the initiation of DNA synthesis in the heterokaryons. The G1 cells treated with CHM for 3-24 h were slow in responding to inducers of DNA synthesis generated by HeLa cells in the heterokaryons. The results suggest that there is a specific point in early G1 that regulates the entry of cells into a cycling state. In the presence of CHM, mitotic cells divide, but the daughter cells fail to enter G1 leading to DNA synthesis, and CHM treatment of G1 cells results in their transient entry into a G0 state.     

Sensitivity of Synchronized Chinese Hamster Cells to Ultraviolet Light

The age response for lethality of Chinese hamster cells to ultraviolet light shows that they are resistant in G(1), sensitive as they move into and through the S phase and resistant again in G(2) and mitosis. Survival curves determined at different times in the cycle reveal that mitotic cells are the most resistant fraction, much more resistant than S cells, and more resistant than either G(1) or G(2) cells. The extent to which the age response is ilfluenced by nucleic acid and protein synthesis was investigated by using inhibitors of these processes. In the presence of inhibitors of DNA or protein synthesis added to G(1) cells before exposure, cell survival neither declines to the minimum survival of S cells nor rises subsequently to the resistance of G(2) cells. If, before exposure, DNA synthesis is arrested in the middle of S, when survival is at a minimum, the subsequent rise in survival during G(2) is not prevented. However when cycloheximide is added before exposure, during the middle of S, this rise is prevented. When actinomycin D, an inhibitor of RNA synthesis is added prior to exposure the age response is affected only slightly. Postirradiation treatment of G(1) and mid-S cells with inhibitors of DNA or protein synthesis maintains survival at a level characteristic of the age of the cells.     

Use of the method of double labeling with H3 and C14-thymidine for identification of cells in different periods of interphase

For the identification of the position of individual cells in G1, S- and G2-periods of mitotic cycle in any heteroploid cell culture, it is suggested to use the Wimber and Quastler radioautographical method of double labeling of cells. It was shown that independent of the basal polidy of the cells by the successive impulse labeling of the cells with H3- and C14-thymidine with the time interval as long as G2 + M, the cells of the G1-period are unlabeled, S-cells are double labeled with C14- and C14 + H3, and G2-cells have only H3-label.     

Molecular signals in B cell activation. II. IL-2-mediated signals are required in late G1 for transition to S phase after ionomycin and PMA treatment

We report that sustained increase of intracellular calcium ion concentration and protein kinase C (PKC) activation maintained throughout the G1 phase of cell cycle do not provide sufficient signals to cause S-phase entry in rabbit B cells, and that additional signals transduced by IL-2 and IL-2 receptor interaction are essential for G1 to S transition. We have shown earlier that rabbit B cells can be activated to produce IL-2 and express functional IL-2 receptors after treatment with ionomycin and PMA. Herein we have compared the response of rabbit PBLs, which contain about 50% T cells, with those of purified B cells. After activation with ionomycin or PMA, comparable numbers of PBLs and B cells entered the cell cycle; but DNA synthesis by the PBL cultures was three to four times higher than that of cultures of purified B cells. Interestingly, IL-2 production by the PBL cultures was also three to four times higher than in B cell cultures, suggesting an involvement of IL-2 in inducing DNA synthesis in these cells. The hypothesis that IL-2, which is produced in early G1, acts in late G1 and is required for G1 to S transition in B cells was supported by the following observations: (i) IL-2 production by B cells was detected as early as 6 hr after activation and preceded DNA synthesis by at least 24 hr. (ii) B cell blasts in G1 (produced by treatment of resting B cells with ionomycin and PMA) showed DNA synthesis in response to IL-2, but showed very little DNA synthesis in response to restimulation with ionomycin and PMA. (iii) A polyclonal rabbit anti-human IL-2 antibody caused nearly complete inhibition of DNA synthesis by B cells activated by ionomycin and PMA. (iv) A PKC inhibitor, K252b, inhibited DNA synthesis in ionomycin and PMA-stimulated cells if added at the beginning of culture but was not inhibitory if added 16 hr later. We conclude that increased [Ca2+]i and PKC activation are not sufficient signals for G1 to S transition in B cells; entry into S is signaled by IL-2, and IL-2-mediated signal transduction probably does not involve increased [Ca2+]i or PKC activation.     

Simian virus 40 induces multiple S phases with the majority of viral DNA replication in the G2 and second S phase in CV-1 cells

The infection of permissive monkey kidney cells (CV-1) with simian virus 40 induces G1 growth-arrested cells into the cell cycle. After completion of the first S phase and movement into G2, mitosis was blocked and the cells entered another DNA synthesis cycle (second S phase). Growth-arrested CV-1 cells replicated significant amounts of viral DNA in the G2 phase with the majority of synthesis occurring during the second S phase. When mimosine-blocked (G1/S) infected cells were released into the cell cycle, a major portion of the viral DNA was detected in G2 with the largest accumulation in the second S phase. The total DNA produced per infected cell was 10-12C with approximately 0.5-2C of viral DNA replicated per cell. Therefore the majority of the DNA per cell was cellular, 4C from the first S phase and approximately 4-6C from the second cellular synthesis phase.     

Significant non-S-phase DNA synthesis visualized by flow cytometry in activated and in malignant human lymphoid cells

The development of a monoclonal antibody to the deoxynucleoside bromodeoxyuridine (BrdU), combined with two parameter flow cytometry, has allowed us to examine large numbers of cells for non-S-phase DNA synthesis. Three human lymphoid cell populations were studied to determine the level of deoxynucleoside (dN) incorporation as a function of DNA content. In each population, non-S-phase DNA synthesis was observed. In a rapidly growing human T-lymphoblastoid cell line (CCRF-CEM), 53% of dN incorporation occurred in G0/G1 plus G2 + M. In chronic lymphocytic leukemia (CLL) cells stimulated with tetradecanoylphorbol acetate (TPA), 45% of the observed burst in thymidine incorporation was found to be localized to G0/G1 cells. Non-S-phase incorporation was not, however, limited to neoplastic cells. Normal human peripheral blood B cells treated with the Cowan strain of Staphylococcus aureus (CSA) undergo a transient burst in thymidine incorporation, but do not go on to divide in the absence of other stimuli. Flow-cytometric analysis showed that 80% of this CSA-stimulated dN incorporation was into G0/G1 cells. These data are consistent with a more dynamic state of DNA synthesis than usually envisioned. Furthermore, the data show that although thymidine incorporation levels are related to incorporation of dN into DNA, they can be unrelated to cell proliferation.     

Escape from X-ray-induced arrest for lens cells stimulated from quiescence: time relationship to RNA, protein, and DNA synthesis

Quiescent cells of the central zone region of the rat lens epithelium were stimulated to enter the proliferation cycle by wounding. RNA synthesis and a corresponding increase in poly(A)+/total RNA reached a peak by Hour 4. Cells progressed into the G1B compartment by Hour 10. A rise in protein synthesis began at Hour 8, and onset of DNA synthesis occurred by Hour 14. The timing of cell cycle progression that allowed escape from a dose of X irradiation that completely inhibited DNA synthesis was investigated. A growth-arrest point was identified at Hour 9 where 10 GY of X irradiation given before, but not after, completely inhibited earliest responding cells from entering DNA synthesis on schedule. Increased quantities of cells entered DNA synthesis on schedule as timing of the X irradiation was moved closer to the end of G1. Based on time relationships, the rise in protein synthesis is correlated with the "sufficient" event for the escape.     

Control of DNA replication and cell growth by inhibiting the export of mitochondrially derived citrate

When citrate export from mitochondria is blocked with 1,2,3-benzenetricarboxylate (BTC) during the G1/S phase of the cell cycle, both DNA synthesis and cell growth are dramatically inhibited in suspension-grown 70Z/3 murine lymphoma cell cultures sustained under otherwise optimal conditions. Synchronized (G0/G1 or G1/S) and unsynchronized cultures are susceptible to this phenomenon. BTC prevents two requirements from being met. (1) It deprives the cytosol of the acetyl CoA necessary for operation of the cholesterogenesis pathway, thereby depleting the supply of mevalonate (MVA) implicated as a requirement for triggering DNA synthesis. (2) It behaves as a nonmetabolizable divalent cation chelator, reducing the availability of Ca2+ and Mg2+, which, in whole cells are both required for DNA synthesis. Such inhibitions are reversible. In whole cells, removal of the inhibitor yields rapid and complete recovery of DNA synthesis. During the prolonged presence of BTC, the addition of MVA plus the Ca2+ ionophore A23187 allows partial recovery of DNA synthesis. In isolated, DNA synthesizing nuclei, on the other hand, the slight inhibition of DNA synthesis by BTC is reversed merely by addition of Mg2+. We conclude that the uninterrupted production of citrate-derived MVA via the mitochondria, at the G1/S boundary of the cell cycle (i.e., subsequent to peak cholesterol synthesis), is mandatory for initiating the duplication of the cell genome. Consequently, by its mitochondrial site of action, BTC can severely limit the otherwise continuous supply of MVA during late G1, which in turn, prevents entry into the S phase, and thereby cell proliferation.