DNA repair replication,DNA breaks and sister-chromatid exchange in human cells treated with adriamycin in vitro

The effects of adriamycin (AM) on DNA repair replication, the frequency of sister-chromatid exchange (SCE), the rate of cell proliferation and the frequency of DNA strand breaks were studied in human cells in vitro. No repair replication was observed in lymphocytes exposed to AM in concentrations up to 10^?3 moles/1. DNA repair replication induced by UV and alkylating agents was not affected by a concentration of AM that completely inhibited cell proliferation (10^?6 moles/1).Fibroblasts exposed to AM at 10^?4 moles/1 in the presence of hydroxyurea showed an increase of strand breaks and cross-links in DNA. When AM was added to UV-irradiated fibroblasts, there was an increase of DNA strand breaks in addition to the breaks caused by UV alone. Similar effects were observed in lymphocytes.A dose-dependent increase of SCE was observed in lymphocytes exposed to low concentrations of AM (<10^?7 moles/1). At higher concentrations the increase of SCE levelled off, and cell proliferation became severely inhibited. There was no evidence of removal of SCE-inducing damage in cells exposed to AM during G₀ or G₁. The level of SCE induced in the third cell cycle after treatment with AM was not different from that induced during the first two cell cycles.These results suggest that the various genotoxic and cytotoxic effects of AM are caused by different types of cellular damage. Moreover, AM-induced DNA damage persists for several cell cycles in human cells in vitro and seems to be resistant to repair activity.     

Changes in the phosphorylation of non-histone chromatin proteins during the cell cycle of HeLa S 3 cells

The phosphorylation of non-histone chromatin proteins in synchronized HeLa S₃ cells was studied in 5 phases of the cell cycle: mitosis, G₁, early and late S, and G₂. The rate of non-histone chromatin protein phosphorylation was found to be maximal during G₁ and G₂, somewhat decreased during S phase, and almost 90% depressed during mitosis. Analysis of the phosphorylated non-histone chromatin proteins by SDS-acrylamide gel electrophoresis showed a heterogeneous pattern of phosphorylation as measured by labeling with ³²P. Significant variations in the labeling pattern were seen during different stages of the cell cycle, and particular unique species appeared to be phosphorylated selectively during certain stages of the cycle.     

The synthesis of acidic chromosomal proteins during the cell cycle of HeLa S-3 cells. II. The kinetics of residual protein synthesis and transport

The kinetics of acidic residual chromosomal protein synthesis and transport were studied throughout the cell cycle in HeLa S-3 cells synchronized by 2 mM thymidine block and selective detachment of mitotic cells. Pulse labeling the cells with leucine-³H for 2 min and then "chasing" the radioactive proteins for up to 3 hr showed that the amount of protein synthesized, transported, and retained in the acidic residual chromosomal protein fraction is greater immediately after mitosis and later in G₁ than in the S or G₂ phases of the cell cycle. During S, only 20–25% of the proteins synthesized and transported to the acidic residual chromosomal protein fraction are chased during the first 2 hr after pulse labeling, whereas up to 40% of the material entering the residual nuclear fraction in mitosis, G₁, and G₂ leaves during a 2 hr chase. Polyacrylamide gel electrophoretic profiles of these proteins, at various times after pulse labeling, reveal that the turnover of individual polypeptides within this fraction has kinetics of synthesis and turnover which are markedly different from one another and undergo stage-specific changes.     

Sister chromatid induction by β-irradiation from incorporated 3H-thymidine: a paradox explained

Sister chromatid exchanges (SCE's) induced by [3H]thymidine (³HdT) of increasing specific activities incorporated over one cycle and 5-bromodeoxyuridine (BrdUrd) over the two following cycles were investigated in synchronised Chinese hamster ovary (CHO) cells. SCEs induced during the first cycle on a T.T template (SCE 1) show little increase with dose compared with those induced in the second cycle on a ³HT.T template (SCE 2) where the linear increase with dose reflects that seen after X irradiation. During the third cycle, SCEs 3.1 and 3.2 are induced on unlabelled T.B or labelled ³HT.B templates respectively. These templates are theoretically present in a 11 ratio after random segregation at second metaphase. Over practically the entire dose range however, the ratio 3.1/3.2, which dereased with dose, was >1.0 and similar to the high values obtained by other workers. At increasing times after BrdUrd introduction, the ratio decreased from >1.0 to <1.0. Measurements showed that the expected 50% level of labelled chromosomes at metaphase in the samples could vary between 42%–59%. Cells with >50% labelled chromosomes were more delayed in the cell cycle due to the ³H-irradiation than those with <50%. Early fixations therefore favoured SCE 3.1 while late favoured SCE 3.2. SCEs due to BrdUrd in ³HT.B and T.B templates showed no synergistic interaction with irradiation-induced SCEs. When these BrdUrd-induced SCEs were removed from the totals then the ³H-induced SCE levels in ³HT.T, and ³HT.B templates (SCE 2 and 3.2) were similar and increased at a similar rate with dose. This was 2–3 times faster than in SCE 1 and 3.1 where the SCE levels due to irradiation were again similar but lower than for 2 and 3.2. The -irradiation source is therefore most effective in inducing SCEs when present in the replicating fork and considerably less effective when it is just behind the fork (SCE 1) and/or in the surrounding chromosomes in the cell.     

Double minutes replicate once during S phase of the cell cycle

Double minutes (dm) characteristically exhibit greater numerical heterogeneity among tumor cells than do chromosomes. The biological basis of this heterogeneity was studied in human carcinoma cell line S 18. Pulse labeling of asynchronous cells with [³H]dThd, continuous labeling of synchronized cells with BrdUrd and prematurely condensed chromosome (PCC) studies of G1 and G2 phase S 18 cells indicate that dm-DNA replicates only once during S phase of the cell cycle. No evidence was found for replication of dm-DNA at G1 phase, G2 phase or mitotis. Cells observed at anaphase show imprecise distribution of dm to daughter cells. These studies suggest numerical heterogeneity of dm results from anomalous mitotic segregation rather than anomalous replication of dmDNA.     

Post-replication DNA repair in barley embryos treated with N-methyl-N-nitrosourea

In sterile cultures of free barley embryos, N-methyl-N-nitrosourea (MNU) caused a decrease in the size of both template [¹⁴C]-labeled DNA and of daughter [³H]DNA strands as determined in alkaline sucrose gradients, and inhibited the rate of [³H]thymidine incorporation. In addition, duplexes containing [³H]-daughter DNA analyzed in BND cellulose contained more single-stranded regions in MNU-treated embryos than in the corresponding control. Incubation of MNU-treated embryos in nutrient medium for up to 18 h after the [³H]-labeling permitted the recovery of small-sized daughter DNA to full-sized strands and led to the enhancement of double-strandedness of DNA duplexes containing [³H]-labeled strands. If [³H]-labeling had been carried out 8–10 h after the MNU treatment, the size of daughter DNA, the proportion of double-strandedness and the rate of thymidine uptake into DNA partially increased in comparison with rates observed when labeling had been done just after or 3 h after the MNU treatment, but these variables did not reach the values of the corresponding controls.     

Surface charge and cell volume of synchronized mouse lymphoblasts (L5178-Y)

Cellular electrophoretic mobility, and therefore, surface charge/ unit area, was found to be constant throughout the cell cycle of synchronized L5178-Y mouse lymphoblasts, remaining at – 1.21 μ sec^?1 V^?1 cm. Measured cell volumes of these synchronized cells increased linearly over the cell cycle and at mitosis each cell divided into two cells, each cell having half of the parent volume. An hypothesis is presented which explains the presence of a mobility peak at mitosis in cells which normally are grown attaching to a glass surface on the basis of differential morphological changes during mitosis; cells such as the L5178-Ys, which do not attach to glass normally, do not undergo such morphological changes at mitosis and, therefore, would not demonstrate a mobility peak at that time.     

Fragmentation of chromatin with 125I radioactive disintegrations.

The DNA in Chinese hamster cells was labeled first for 3 h with [3H]TdR and then for 3 h with [125I]UdR. Chromatin was extracted, frozen, and stored at -30 degrees C until 1.0 X 10(17) and 1.25 X 10(17) disintegrations/g of labeled DNA occurred for 125I and 3H respectively. Velocity sedimentation of chromatin (DNA with associated chromosomal proteins) in neutral sucrose gradients indicated that the localized energy from the 125I disintegrations, which gave about 1 double-strand break/disintegration plus an additional 1.3 single strand breaks, selectively fragmented the [125I] chromatin into pieces smaller than the [3H] chromatin. In other words, 125I disintegrations caused much more localized damage in the chromatin labeled with 125I than in the chromatin labeled with 3H, and fragments induced in DNA by 125I disintegrations were not held together by the associated chromosomal proteins. Use of this 125I technique for studying chromosomal proteins associated with different regions in the cellular DNA is discussed. For these studies, the number of disintegrations required for fragmenting DNA molecules of different sizes is illustrated.     

Mapping of sister-chromatid exchanges in human chromosomes using G-banding and autoradiography.

Lumphocytes were pulse-labelled with [3H] thymidine. Following G-banding, the cells were autoradiographed and 46 in their third post-labelling division selected. The locations of 611 sister-chromatid exchanges (SCE's) which had occurred in the previous two cell cycles were recorded as label discontinuities along identified chromosomes. Between particular chromosomes, SCE frequency was proportional to chromosome length. SCE frequency distributions within particular chromosomes fitted Poisson expectations. There was no over-representation of exchanges in centromeric regions, or in the C-banded regions of chromosomes 1, 9 and 16. A trend of increased frequency of SCE in darkly G-banded regions and in relatively darkly banded chromosomes was evident. The apparent excess of SCE in dark G-bands could be considered to be a consequence of the more condensed state of the DNA in these regions in the interphase nucleus relative to the DNA in pale G-band regions. Such compaction could result in an enhanced probability of SCE and a reduced probability of gross inter- or intra-change involving these regions. In contrast, the more extended interphase state of the DNA in pale G-banded regions would allow non-homologous exchange and account for the preferred location of X-ray-induced exchange events to pale G-bands.     

Mitochondrial protein synthesis in chinese hamster cells (line CHO) synchronized by isoleucine deprivation

Mitochondrial protein synthesis was measured in line CHO cells after phases of the cell cycle were synchronized by isoleucine deprivation or mitotic selection. Maximum incorporation of [³H] leucine into mitochondrial polypeptides occurred within 2 hours after isoleucine was added to initiate G₁ traverse. In cells synchronized in G₁ by mitotic selection, the rate of mitochondrial protein synthesis was fairly constant throughout the cell cycle. SDS-polyacrylamide gel electrophoretic profiles of labeled mitochondrial polypeptides were similar in cells synchronized by either isoleucine deprivation or mitotic selection. Obvious changes in the distribution of polypeptides were not detected during various phases of the cell cycle. The increased rate of incorporation of [³H] leucine into mitochondrial polypeptides after reversal of G₁-arrest may indicate that mitochondrial protein synthesis and possibly mitochondrial biogenesis are synchronized in CHO cells deprived of isoleucine.     

The cell kinetics of the adaptation of the human esophagus to organ culture

Summary The adaptation of normal human esophageal explants to organ culture for the first 33 d of in vitro growth was evaluated using histomorphology and [³H]TdR autoradiography combined with mitotic blockade. On the 3rd d in culture, extensive desquamation of superficial cells reduced the epithelium to about four cell layers. Thereafter, the epithelium remained atrophic, with a relative increase in basal and suprabasal cells. The percentage of cells synthesizing DNA was greatest from Day 4 through 8, just after desquamation, and reached a maximum on Day 4 (24 h [³H]TdR labeling index of 62%). The labeling index (LI) fluctuated, thereafter, but remained high (26% on Day 33). During the last 6 h of each [³H]TdR labeling interval, mitosis was blocked by colcemid. The 6 h mitotic rate (MR) was a reasonably constant fraction of the LI (maximum at 4 d: MR=1.44%), but was much lower than predicted by [³H]TdR labeling indicating the loss of large numbers of cells after DNA synthesis but before or during mitosis. Unlabeled mitotic figures appeared between Days 1 to 3 and 6 to 33, suggesting that the epithelium initially contained a considerable population of cells arrested or delayed in G₂ and continued to generate cells that remained in premitosis longer than 24 h. These results indicate that the atrophy observed in vitro is characterized by a relative increase in the basal and suprabasal cell category, a high replication rate, initial recruitment of cells arrested in premitosis, and rapid cell turnover with significant loss of cells at the premitotic or mitotic step, or both. Thus it seems that human esophageal epithelium grown in organ culture is a satisfactory substrate for experimentation (for example, in vitro carcinogenesis) that requires cell replication. However, there are major differences between the kinetics of esophageal epithelium in vivo and in vitro. Supported in part by Contract NOI-CP-75909 and NOI-CP-25604-59 from the National Cancer Institute, Bethesda, MD.     

NUCLEOLAR AND NUCLEAR RNA SYNTHESIS DURING THE CELL LIFE CYCLE IN MONKEY AND PIG KIDNEY CELLS IN VITRO

The incorporation of 5-³H-uridine and 5-³H-cytidine into nucleolar and nonnucleolar RNA in the nucleus of monkey and pig kidney cells was measured in vitro during the cell life cycle. Time-lapse cinematographic records were made of cells during asynchronous exponential proliferation, in order to identify the temporal position of individual cells in relation to the preceding mitosis. Immediately following cinematography, cells were labeled with uridine-³H and cytidine-³H for a short period, fixed, and analyzed by radioautography. Since the data permit correlation of the rate of RNA labeling with the position of a cell within the cycle, curves could be constructed describing the rate of RNA synthesis over the average cell cycle. RNA synthesis was absent in early telophase, and rose very abruptly in rate in late telophase and in very early G₁ in both the nucleus and the reconstituting nucleolus. Thereafter, through the G₁ and S periods the rate of nuclear RNA synthesis rose gradually. When we used a 10-min pulse, there was no detectable change in the rate for nucleolar RNA labeling in monkey kidney cells during G₁ or S. When we used a 30-min labeling time, the rate of nucleolar RNA labeling rose gradually in pig kidney cells. With increasing time after mitosis, the data became more variable, which may, in part, be related to the variation in generation times for individual cells.     

The activity of total histone H1 kinases is related to growth and commitment points while the p13suc1-bound kinase activity relates to mitoses in the alga Scenedesmus quadricauda

Under optimal growing conditions, synchronous cultures of the alga Scenedesmus quadricauda underwent three DNA replications and three mitoses during one cell cycle. This resulted in eight daughter cells. By different illumination regimes and temporal addition of cycloheximide, cell divisions resulting in two, four or eight daughter cells per cycle were obtained. The selected cell cycle patterns differed in timing of commitment points, the number of nuclear divisions, and their positioning in the cell cycle. These distinct cell cycle patterns allowed to assess the correlation of histone H1 kinase activity with commitment points and mitoses. The activity of the histone H1 kinases was assayed in cellular protein extracts and after affinity purification using the p13^suc1 protein. The main peaks of kinase activity in the cellular extract were found to correlate with the commitment points. Small histone H1 kinase activity peaks were also found which preceded the nuclear division. Contrary to the histone H1 kinase activity of cellular extracts, the p13^suc1-bound kinase activity preceded the nuclear division, whilst its activity was negligible at the commitment points. Being able to manipulate the timing of commitment points and cell division by manipulating experimental conditions, we could precisely match the commitment points to an as yet unidentified histone H1 kinase activity and mitosis to p13^suc1-bound CDK activity during a particular cell division pattern with overlapping cycles. This provides molecular evidence, that local activation of CDKs regulates distinct events of the cell cycle.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

STUDIES ON THE DIVISION CYCLE OF MAMMALIAN CELLS : V. Modifications of Time Parameters by Different Steady-State Culture Conditions

In cultures of murine neoplastic mast cells, the duration of different phases of the division cycle (G₁, S, G₂, and mitosis [M]) was determined under optimal and several well-defined suboptimal growth conditions. Two methods of evaluation were applied to the same culture system: first, the relative number of G₁, S, G₂, and M cells was determined by pulse labeling of samples with thymidine-³H and subsequent radioautography in conjunction with a microfluorometric technique permitting rapid measurements of cellular DNA content; second, after pulse labeling with thymidine-³H, the variations with time of the mitotic labeling index were analyzed. Suboptimal culture conditions were obtained by reducing the concentration of single essential medium components (leucine, glucose, or serum) or by the addition of specific metabolic inhibitors (actinomycin D, amethopterin). Growth-limiting culture conditions resulted in increased generation times. Even under control conditions, the cell number doubling time exceeded the generation time, and this difference was more pronounced in suboptimal media. Under most of the suboptimal conditions tested, the increase in generation time was attributable primarily to an extended duration of the G₁ phase. Under certain growth-limiting conditions, however, other phases were also prolonged. In addition, the variabilities of the generation time and of certain cell cycle phases were increased under suboptimal culture conditions. Results obtained by the two methods of evaluation were, in general, in good agreement with each other. Some differences were, however, observed and interpreted in terms of cell death and/or asymmetric frequency distributions of cell cycle parameters.     

Effect of 5-bromodeoxyuridine substitution on sister chromatid exchange induction by chemicals

The fluorescence-plus-Giemsa (FPG) technique for analysis of sister chromatid exchange (SCE) is widely used as an assay for mutagenic carcinogens. There is very little information, however, on whether incorporation of the bromodeoxyuridine (BrdU) necessary for visualization of SCEs affects the sensitivity of the SCE test system to different chemical agents. We have investigated the effect of BrdU incorporation on SCE induction by labeling cells with BrdU for either the first cell cycle or the first and second cell cycles. The cells were then treated with bleomycin, which produces DNA strand breakage; proflavine, which intercalates into DNA; mitomycin C, which produces monoadducts and DNA crosslinks; or aphidicolin, which inhibits DNA polymerase . Chemicals were added before BrdU exposure or during the first, second, or both cell cycles. Only mitomycin C, which induces long-lived lesions, elevated the SCE frequency when cells were treated before BrdU labeling. When bleomycin, proflavine, or mitomycin C was present concurrently with BrdU, the frequency of SCEs was increased independently of the BrdU labeling protocol. Aphidicolin, on the other hand, induced more SCEs when present for the second cell cycle, when DNA replicates on a template DNA strand containing BrdU. We also examined the induction of SCEs in the first cell cycle (twins) and in the second cell cycle (singles) after continuous treatment of cells with BrdU and the test chemicals. Only aphidicolin increased SCE frequency in the second cell cycle. These results indicate that aphidicolin, but not bleomycin, proflavine, or mitomycin C, affects BrdU-substituted DNA and unsubstituted DNA differently. This type of interaction should be taken into consideration when the SCE test is used as an assay system.     

Non-random segregation of DNA strands in Escherichia coli B-r

The segregation of DNA strands during growth of Escherichia coli$\text{B}\text{r}$ has been studied under conditions in which the chromosomal configuration and the ancestry of the cells during growth and division were known. Cells containing either one or two replicating chromosomes were pulse-labeled with [³H]thymidine, and the location of the radioactivity within chains of cells formed by growth in methylcellulose was determined by autoradiography. The locations of the radioactive cells within chains obtained after the second, third and fourth divisions were consistent with the co-segregation of only one of the replicating strands of each chromosome and a fixed region of the cell into daughter cells. The attachment of this strand to the region appeared to become permanent at the time the strand was used for the first time as a template. It is concluded that the segregation of DNA molecules into daughter cells is non-random in E. coli B/r.     

MODE OF GROWTH OF THE JEJUNAL CRYPT CELLS OF THE RAT: AN AUTORADIOGRAPHIC STUDY USING DOUBLE LABELLING WITH 3H- AND 14C-THYMIDINE IN LOWER AND UPPER PARTS OF CRYPTS

The frequency distribution of cells through the mitotic cycle in lower and upper portions of jejunal crypts of the rat was examined by the ³H-¹⁴C-thymidine double labelling technique. Isolated crypts were cut perpendicular to the longitudinal axis so that the percentage of cells in the lower portion varied from 16 to 74 %. The lower and upper portion of the same crypt were squashed separately on one microscope slide and the number of ³H- and ¹⁴C-only labelled cells were scored to determine the flow rate into and out of S for the two portions. The mitotic cycle and its phases of the crypt epithelial cells were also determined. For lower portions of crypts which contained less than 40 % of the total cell number in that crypt the flow rate into S was about 1–7 times that of the flow rate out of S indicating that nearly every mitosis in this region produced two proliferative daughter cells. As the proportion of cells in the lower part of the crypt increased the quotient of the flow rate into S divided by the flow rate out of S decreased, and approached the steady state value of 1 0 in lower portions containing 60–74 % of the cells. For upper portions of crypts which contained less than 40% of the total crypt cells the flow rate into S was about 0 2 times that of the flow rate out of S, indicating that in this region mitoses predominantly produced non-proliferative daughter cells. The results obtained were in good agreement with the model of crypt cell proliferation proposed by Cairnie, Lamerton & Steel (1965b).