Redistribution of bone marrow cells according to mitotic cycle phases after the action of agents altering the intracellular concentration of cyclic nucleotides

The method of flow cytofluorometry was used to determine the distribution of murine bone marrow cells along the phases of the cell cycle in normal mice (CBA X C57Bl) F1 after the whole body equal X-ray irradiation, after irradiation in combination with burn, after administration of imidazole, insulin and caffeine, and after the treatment of cells by acetylcholine. In non-irradiated mice insulin and caffeine induced an increased ratio of bone marrow cells in G0 and G1 and a reduced one in S phase. Imidazole increased the number of G2- and M-cells by 1.5 times only in regenerating bone marrow of irradiated mice. After X-ray irradiation of mice at a dose of 2.3 Gy, reducing the percentage of cells in S and increasing it in G2 and M phases, insulin, acetylcholine and caffeine were found to decrease the number of cells in G2 and M phases: besides, caffeine and acetylcholine increased the percentage of S-phase cells. The data obtained are discussed in terms of possibility of normalization of bone marrow cell proliferation broken after exposure to physical stress-factors.     

Abnormal retention of X-irradiated ataxia-telangiectasia fibroblasts in G2 phase of the cell cycle: cellular RNA content, chromatin stability and the effects of 3-aminobenzamide

We have addressed three aspects of the abnormal sensitivity of SV40 transformed ataxia-telangiectasia (A-T) fibroblasts to X-irradiation, namely: (a) the radiogenic perturbations in cell-cycle traverse analysed by flow cytometry; (b) the involvement of 3-aminobenzamide-sensitive processes in cellular recovery in terms of viability and release from G2 + M phase delay; and (c) the functional and structural integrity of cells delayed in G2 + M phase using acridine orange as a probe for cellular RNA content and chromatin structure. We report that A-T cells show a dose-dependent and survival-related abnormal retention in G2 + M phase due to the lack of a recovery process, despite the capacity of such cells to synthesize ribosomal RNA and maintain the structural integrity of chromatin. Evidence is presented that the recovery process is dependent upon poly(ADP ribosyl)ation activity in both normal and A-T cells except that in the latter cell type recovery potential is rapidly saturated in terms of X-ray dose.     

Cellular radiation effects and hyperthermia cell cycle kinetics of radiation sensitive mutants of Saccharomyces cerevisiae after X-irradiation and hyperthermia

Radiosensitive mutants rad2, rad9, and rad51 of Saccharomyces cerevisiae were X-irradiated with 120 Gy or 60 Gy, heated at 50 degrees C for 30 min or treated with a combination of both and incubated in nutrient medium at 30 degrees C. Cell number, percentage of budding cells, and cell cycle progression were determined in 45-min intervals. Cell cycle kinetics were investigated by flow cytofluorometry. Hyperthermia leads mainly to a lengthening of G1, whereas X-rays arrest cells of the rad2 and rad9 mutant in G2 and the rad51--mutant additionaly in a state with DNA contents above G2. Cell division delay is influenced by oxygen in all strains but to a lesser extent in the rad2 mutant. The effect of the combined treatment appears to be merely additive in the rad2 and rad9 mutant while the rad51 mutant is sensitized to X-irradiation by hyperthermia. No selective action of hyperthermia on hypoxic cells was found.     

Role of topoisomerase II in the response of mammalian cells to the action of ionizing radiation. I. Change in the mitotic cell cycle of Chinese hamster CHO K1, irradiated with x-rays, after the action of novobiocin at a high concentration]

Flow cytometry was used to study cell cycle recovery in X-irradiated Chinese hamster cells after action of novobiocin, an inhibitor of topoisomerase II. A prolonged treatment with 1 mM novobiocin (20-30 h) of intact cells results in the G2 + M delay. Novobiocin treatment of 5 Gy-irradiated cells results in a slight delay in cell exit from G1 into S phase and in a much longer G2-delay if compared with X-irradiated cells. These data allow to suggest an involvement of topoisomerase II in cell response to ionizing radiation.     

Fluorescence kinetics in HeLa cells after treatment with cell cycle arrest inducers visualized with Fucci (fluorescent ubiquitination-based cell cycle indicator)

Fucci (fluorescent ubiquitination-based cell cycle indicator) is able to visualize dynamics of cell cycle progression in live cells; G1- and S-/G2-/M-phase cells expressing Fucci emit red and green fluorescence, respectively. This system could be applied to cell kinetic analysis of tumour cells in the field of cancer therapy; however, it is still unclear how fluorescence kinetics change after various treatments, including exposure to anticancer agents. To explore this, we arrested live HeLa cells expressing the Fucci probes at various cell cycle stages and observed the fluorescence, in conjunction with flow cytometric analysis. X-irradiation, HU (hydroxyurea) and nocodazole arrest cells at G2/M boundary, early S-phase and early M-phase, respectively. Although X-irradiation and HU treatment induced similar accumulation kinetics of green fluorescent cells, nocodazole treatment induced an abnormal red fluorescence at M phase, followed by accumulation of both red and green fluorescent cells with 4N DNA content. We conclude that certain agents that disrupt normal cell cycle regulation could cause unexpected fluorescence kinetics in the Fucci system.     

X-irradiation--induced changes in the progression of type B spermatogonia and preleptotene spermatocytes

In response to induced DNA damage, proliferating cells arrest in their cell cycle or go into apoptosis. Ionizing radiation is known to induce degeneration of mammalian male germ cells. The effects on cell-cycle progression, however, have not been thoroughly studied due to lack of methods for identifying effects on a particular cell-cycle phase of a specific germ cell type. In this study, we have utilized the technique for isolation of defined segments of seminiferous tubules to examine the cell-cycle progression of irradiated rat mitotic (type B spermatogonia) and meiotic (preleptotene spermatocytes) G1/S cells. Cells irradiated as type B spermatogonia in mitotic S phase showed a small delay in progression through meiosis. Thus, it seems that transient arrest in the progression can occur in the otherwise strictly regulated progression of germ cells in the seminiferous epithelium. Contrary to the arrest observed in type B spermatogonia and in previous studies on somatic cells, X-irradiation did not result in a G1 delay in meiotic cells. This lack of arrest occurred despite the presence of unrepaired DNA damage that was measured when the cells had progressed through the two meiotic divisions.     

Comparative studies on the heat-induced thermotolerance of protein synthesis and cell division in synchronized mouse neuroblastoma cells

Mouse neuroblastoma (N2A) cells react to a heat treatment by inhibition of DNA and protein synthesis and induction of cell cycle progression delay. Mitotic delay of heat-treated G1 cells correlates with reduction of protein synthesis and is due to an extensive delay of entrance into S phase, while the G2 phase of these cells is shortened. Mitotic delay of heat-treated G2 cells is more than in G1 cells and no correlation with protein synthesis reduction is found. In heat-treated G1 phase cells, both protein synthesis and cell cycle progression become thermotolerant to a second incubation at increased temperature. Moreover, the process of DNA synthesis becomes thermotolerant. In contrast, when heat-treated G1 phase cells have progressed into G2 phase and are then incubated at increased temperature, this G2 phase delay is not diminished. Apparently, additional targets for hyperthermia are present in late S and G2 phase cells.     

Reprimo, a new candidate mediator of the p53-mediated cell cycle arrest at the G2 phase

A novel gene, Reprimo, in which induction in cells exposed to X-irradiation is dependent on p53 expression, has been isolated. Ectopic p53 expression results in the induction of its mRNA. Reprimo is a highly glycosylated protein and, when ectopically expressed, it is localized in the cytoplasm and induces G(2) arrest of the cell cycle. In the arrested cells, both Cdc2 activity and nuclear translocation of cyclin B1 are inhibited, suggesting the involvement of Reprimo in the Cdc2.cyclin B1 regulation pathway. Thus, Reprimo may be a new member involved in the regulation of p53-dependent G(2) arrest of the cell cycle.     

An unusual radiation-induced G2 arrest in the zygote of the BALB/c mouse strain

Female mice of the BALB/c strain were superovulated, mated with males of the same strain, and irradiated with 1 Gy of X-rays at hourly intervals during the first cell cycle of the embryos. Two types of effects were found in the embryos, depending on the time of X-irradiation. When irradiation was delivered between 14 and 21 h after human chorionic gonadotrophin (hCG) injection, cultured two-cell embryos developed normally up to the morula stage, where a high mortality occurred. On the other hand, when irradiation was given between 17 and 24 h after hCG injection, a high proportion of the eggs was unable to cleave and remained blocked at the one-cell stage. Cytofluorometric analysis of the pronuclear DNA content of uncleaved zygotes showed that DNA synthesis was unaffected by X-irradiation, and that they were blocked in G2 phase of the first cell cycle. Similar studies on other strains, as well as reciprocal crosses between BALB/c and F1(female BALB/c X male C57 BLACK) mice showed that the 'one-cell block' is determined by the maternal genotype and results most probably from a direct action of X-rays on a radiosensitive cytoplasmic factor necessary for the first embryonic cell division, and appearing 17 h after hCG injection. A high proportion of blocked zygotes (30-40 per cent) recovered partially, cleaved with a delay of about 20 h, and died soon after, almost none of them being able to reach the blastocyst stage. At the time of maximum radiosensitivity, the LD50 for development up to the blastocyst stage was 0.95 Gy.     

Heterologous expression of the human cyclin-dependent kinase inhibitor p21Cip1 in the fission yeast, Schizosaccharomyces pombe reveals a role for PCNA in the chk1+ cell cycle checkpoint pathway.

Fission yeast cells expressing the human gene encoding the cyclin-dependent kinase inhibitor protein p21Cip1 were severely compromised for cell cycle progress. The degree of cell cycle inhibition was related to the level of p21Cip1 expression. Inhibited cells had a 2C DNA content and were judged by cytology and pulsed field gel electrophoresis to be in the G2 phase of the cell cycle. p21Cip1 accumulated in the nucleus and was associated with p34cdc2 and PCNA. Thus, p21Cip1 interacts with the same targets in fission yeast as in mammalian cells. Elimination of p34cdc2 binding by mutation within the cyclin-dependent kinase binding domain of p21Cip1 exaggerated the cell cycle delay phenotype. By contrast, elimination of PCNA binding by mutation within the PCNA-binding domain completely abolished the cell cycle inhibitory effects. Yeast cells expressing wild-type p21Cip1 and the mutant form that is unable to bind p34cdc2 showed enhanced sensitivity to UV. Cell cycle inhibition by p21Cip1 was largely abolished by deletion of the chk1+ gene that monitors radiation damage and was considerably enhanced in cells deleted for the rad3+ gene that monitors both DNA damage and the completion of DNA synthesis. Overexpression of PCNA also resulted in cell cycle arrest in G2 and this phenotype was also abolished by deletion of chk1+ and enhanced in cells deleted for rad3+. These results formally establish a link between PCNA and the products of the rad3+ and chk1+ checkpoint genes.     

He—Ne激光照射对成纤维细胞内[Ca^2＋]i浓度影响的流式细胞计测定

目的：Ｈｅ－Ｎｅ激光照射治疗的机理不明,激光照射引起细胞内Ｃａ＾２＋水平变化,为治疗机理提供理论依据。方法：Ｈｅ－Ｎｅ激光照射引起鼠成纤维细胞Ｌ９２９内［Ｃａ＾２＋］ｉ的变化,用ＨＯ３４２对细胞ＤＮＡ活性染色,Ｆｌｕｏ－３ＡＭ对细胞内Ｃａ＾２＋染色,利用ＦＣＭ同时定量分析细胞ＤＮＡ和细胞内Ｃａ＾２＋的变化。结果：激光照射１５ｍｉｎ（光剂量１１．８１Ｊ／ｃｍ＾２后,ＦＣＭ分析可见ＤＮＡ分布直方图右移     

The effect of caffeine on the duration of the mitotic phase cycle in CHO-K1 Chinese hamster cells, irradiated with x-rays

Alterations in the duration of mitotic cycle phases in X-irradiated Chinese hamster cells CHO K1 after caffeine (CF) treatment are studied. Delays in S- and G2-phases, induced by 1 and 5 Gr of X-irradiation, are partially or completely decreased by 1 mM or 5 mM CF, respectively. When CF is removed from the medium after irradiation, delays in S- and G2-phases are seen again, however long (0-12 hours) CF remains in the medium. The data obtained allow to suggest that since CF results in a radioresistant DNA synthesis, it may also postpone delays in S- and G2-phases, while cells are progressing through the cell cycle.     

Induction of the differentiation of synchronized HL-60 leukemia cells by tiazofurin

Tiazofurin is an effective inducer of the maturation of HL-60 promyelocytic leukemia cells, as monitored by increased phagocytic ability and the capacity to reduce nitroblue tetrazolium (NBT). The antimetabolite acts as a potent inhibitor of IMP dehydrogenase, which results in a profound depression in the cellular levels of guanine nucleotides. Flow cytometric analysis of DNA histograms indicated that the commitment of HL-60 cells to differentiate when exposed to tiazofurin was preceded by a transient delay in the G1 phase of the cell cycle. HL-60 leukemia cells enriched in the various phases of the cell cycle by centrifugal elutriation were utilized to further characterize the relationship between the phase of the cell cycle and the commitment to enter a pathway of differentiation. Fractions composed mainly of G1 cells demonstrated an increased capacity to mature when exposed to tiazofurin, whereas fractions containing cells from the S and G2 + M phases of the cell cycle had a lower ability to enter a differentiation pathway. The findings suggest that the commitment of HL-60 cells to mature when exposed to tiazofurin is mediated during the G1 phase of the cell cycle.     

Ion content and the response of L5178Y-R and L5178Y-S cells to X rays and ionophore A23178

Summary We examined the response of L5178Y-S (radiosensitive, LY-S) and L517SY-R (radioresistant, LY-R) lymphoblasts to X-irradiation with concomittant treatment with divalent cation ionophore, A23187 (3 h or 5 h, 5 µg/ml). Cells treated with A23187 alone progressed through the cell cycle more slowly than the untreated cells and their cloning efficiency was reduced. In both cell strains the ionophore prolonged duration of the postirradiation mitotic delay. Radiation-induced inhibition of DNA synthesis was reversed by A23187 in LY-S but not in LY-R cells.Cells subjected to the ionophore treatment survived X-irradiation in almost the same way as untreated cells, as if the effect of A23187 treatment were reversed by irradiation. There was also a reversion in the ion content: A23187 caused a marked increase in Na⁺ content and a decrease in K⁺ content, irradiation itself did not change the ion content, whereas in the A23187-treated cells it restored almost the same pattern as that found in the control cells. We found less Mg²⁺ ions in LY-S cells after treatment with A23187 and A23187 + X than in LY-R cells, in relation to untreated (control) cells. These observations point to the possible importance of ion transport for recovery from radiation damage.     

Delay of cell cycle progression after X-irradiation of synchronized populations of human cells (NHIK 3025) in culture.

The effect of X-irradiation on the cell cycle progression of synchronized populations of the human cell line NHIK 3025 has been studied in terms of the radiation-induced delay of DNA replication and cell division. Results were obtained by flow cytometric measurement of histograms of cellular DNA content and parallel use of conventional methods for cell cycle analysis, such as pulse labelling with [3H]thymidine and counting of cell numbers. The two sets of methods were generally in good agreement, but the advantages of employing two independent techniques are pointed out. Irradiation was found to have a minor influence on DNA replication. As compared with unirradiated populations, half-completed DNA replication was 20--30 min delayed in populations 580 rad in mid-G1 or 290 rad in early S. Cell cycle progression was markedly delayed in G2. The sensitivity induction of this delay was 0.6 min/rad for populations irradiated in mid-G1, and 1.4 min/rad for populations irradiated in early S.     

Cellular and nuclear volume during the cell cycle of NHIK 3025 cells

The distribution of cellular and nuclear volume in synchronous populations of NHIK 3025 cells, which derive from a cervix carcinoma, have been measured by electronic sizing during the first cell cycle after mitotic selection. Cells given an X-ray dose of 580 rad in G1, were also studied. During the entire cell cycle the volume distribution of both cells and nuclei is an approximately Gaussian peak with a relative width at half maximum of about 30%. About half of this width is due to imperfect synchrony whereas the rest is associated with various time invariant factors. During S the mean volume of the cells grows exponentially whereas the nuclear volume increases faster than for exponential kinetics. Hence, although cellular and nuclear volumes are closely correlated, their ratio does not remain constant during the cell cycle. Volume growth during the first half of G1 is negligible especially for nuclei where the growth appears to be closely associated with DNA-synthesis. For unirradiated cells the growth of cellular and nuclear volume is negligible also during G2 + M. In contrast, the X-irradiated cells continue to grow during the 6 hr mitotic delay with a rate that is constant and about half of that observed in late S. Hence, radiation induced mitotic delay does not appear merely as a lengthening of an otherwise normal G2. During G1 and S the irradiated cells were identical to unirradiated ones with respect to all the parameters measured.     

Polyploidization of rat hepatocytes induced by x-ray radiation at different periods of the cell cycle

As determined by the yield of polyploid hepatocytes after X-irradiation of rats with a dose of 6 Gy the S-stage of the cell cycle was most radiosensitive; as to the yield of cells with chromosome aberrations the middle of the G1-stage was the most radiosensitive period of the cell cycle. The differences in the radiosensitivity of the cell cycle stages indicated that although primary lesions were similar molecular mechanisms leading to tre final effect were essentially different.