ON THE RESTING STAGES OF THE JB-1 ASCITES TUMOUR

Cytophotometric determination of single-cell DNA after repeated ³H-thymidine labelling of the JB-1 ascites tumour in the plateau phase of growth showed a massive accumulation of unlabelled cells with both G₁ and G₂ content. Autoradiography combined with cytophotometry or colcemid block demonstrated that some of these unlabelled cells were rapidly triggered into the cell cycle when plateau tumours were transferred to new hosts. This indicated that tumour cells may be held up in non-cycling stages corresponding to both the G₁ and the G₂ phase of the cell cycle.     

Proliferating cell nuclear antigen and Ki-67 antigen expression in human haematopoietic cells during growth stimulation and differentiation

Abstract. By flow cytometric dual parameter analysis of proliferating cell nuclear antigen (PCNA) and the Ki-67 antigen a detailed cell cycle analysis can be performed. In this study the co-ordinated expression of these two growth-related antigens was investigated in human haematopoietic cells at entrance into the cell cycle as well as at exit from the cycle. In mitogen-stimulated peripheral blood lymphocytes entering the first cell cycle, the Ki-67 antigen was found to be expressed in S phase cells and not in G₁ cells. Thus, the Ki-67 antigen expression in PCNA-positive S phase cells differed between continuously cycling cells and cells entering the cell cycle. Based on this difference, it was possible to visualize and evaluate the recruitment of cells into the first cell cycle from a resting stage. This new cell cycle parameter can give additional information concerning tumour growth. The Ki-67 antigen was also studied during different stages of G₁ and was found to be expressed at high levels in early G₁ cells compared with other parts of G₁.     

Synthesis of protein and mRNA is necessary for transition of suspension-cultured Catharanthus roseus cells from the G1 to the S phase of the cell cycle

The effects of inhibition of the synthesis of protein, mRNA or rRNA on the progression of the cell cycle have been analyzed in cultures of Catharanthus roseus in which cells were induced to divide in synchrony by the double phosphate starvation method. The partial inhibition of protein synthesis at the G₁ phase by anisoniycio or cycloheximide caused the arrest of cells in the G₁ phase or delayed the entry of cells into the S phase. When protein synthesis was partially inhibited at the S phase, cell division occurred to about the same extent as in the control. When asynchronously dividing cells were treated with cycloheximide, cells accumulated in the G₁ phase, as shown by flow-cytometric analysis. The partial inhibition of mRNA synthesis by α-amanitin at the G₁ phase caused the arrest of cells in the G₁ phase, although partial inhibition of mRNA synthesis at the S phase had little effect on cell division. In the case of inhibition of synthesis of rRNA by actinomycin D at the G₁ phase, initiation of DNA synthesis was observed, but no subsequent DNA synthesis or the division of cells occurred. However, the addition of actinomycin D during the S phase had no effect on cell division. These results suggest that specific protein(s), required for the progression of the cell cycle, are synthesized in the G₁ phase, and that the mRNA(s) that encode these proteins are also synthesized at the G₁ phase.     

Normal G1/S transition and prolonged S phase within one cell cycle after seeding cells in the presence of an ornithine decarboxylase inhibitor

Abstract. We have previously found that DNA replication was affected within one cell cycle after seeding Chinese hamster ovary (CHO) cells in the presence of the polyamine biosynthesis inhibitor 2-difluoromethylornithine (DFMO). We could, however, not rule out if this was due to an effect on the G₁/S transition and/or on DNA synthesis elongation. In the present paper, we use a bromodeoxyuridine-flow cytometric method to more specifically study the G₁/S transition, the S phase length, and the progression of cells from S phase through G₂+ M and into G₁, after seeding plateau phase CHO cells at low density in the absence or presence of 5 mM DFMO. We report here that DFMO-induced polyamine depletion increased the length of the S phase within one cell cycle after seeding of CHO cells in the presence of the inhibitor. No effect on the G₁/S transition was observed until 2 days after seeding, suggesting that a DFMO-induced lengthening of the G₁ phase occurred later than the effect on S phase progression. These results imply that the G₂+ M phase was not prolonged until 2 days after seeding CHO cells in the presence of DFMO.     

Cell-cycle dependence of a ganglioside glycosyltransferase activity and its inhibition by enkephalin in a neurotumor cell line

Abstract: Rat glioma mouse neuroblastoma hybrid neurotumor cells (NG108-15), synchronized by amino acid deprivation, showed a cell-cycle-dependent peak of activity of a ganglioside N-acetylgalactosaminyl transferase 14-24 h following release from the cell cycle block (S/G₂ phase). Maximal expression of two typical lysosomal hydrolases, N-acetyl-β-hexosaminidase and β-galactosidase, occurred between 18 and 21 h following release (S phase), declining to G₁ phase levels during the peak of N-acetylgalactosamine (GalNAc) transferase activity. In addition, glycosyltransferase activity in G₂ phase cells showed an increase in apparent V_max (suggesting the presence of more enzyme/mg of cell protein) and apparent binding affinity for uridine diphosphate N-acetylgalactosamine (UDP-GalNAc) (32 versus 14 M) when compared to transferase activity in the G₁ phase. However, the opioid peptide enkephalin [D-Ala², o-Leu⁵], which inhibits ganglioside GalNAc transferase activity in unsynchronized NG108-15 cultures, was much more inhibitory in whole cells 8 h after release from the cell cycle block (G₁ phase) than in cells 20 h after release (G, phase), with 50% inhibition occurring at 2 ± 10^-9M and 2 ± 10^-7M, respectively. These results suggest that the GalNAc transferase activity is regulated in more than one way during the cell cycle, since both V_max and K_m changes are observed, and that the cyclic AMP-dependent mechanism by which opiates reduce transferase activity is receptor mediated and cell cycle dependent.     

Cell cycle progression in human cells following re-oxygenation after extreme hypoxia: consequences concerning initiation of DNA synthesis

Abstract. The initiation of DNA synthesis and further cell cycle progression in cells during and following exposure to extremely hypoxic conditions in either G₁ or G₂+M has been studied in human NHIK 3025 cells. Populations of cells, synchronized by mitotic selection, were rendered extremely hypoxic (< 4 p.p.m. O₂) for up to 24n h. Cell cycle progression was studied from flow cytometric DNA recordings. No accumulation of DNA was found to take place during extreme hypoxia. Cells initially in G₁ at the onset of treatment did not enter S during up to 24 h exposure to extreme hypoxia, but started DNA synthesis in a highly synchronous manner within 1.5 to 2.25 h after reoxygenation. The duration of S phase was only slightly affected (increased by ≅10%) by the hypoxic treatment. This suggests that the DNA synthesizing machinery either remains intact during hypoxia or is rapidly restored after reoxygenation. Cells initially in G₂ at the onset of hypoxia were able to complete mitosis, but further cell cycle progression was blocked in the subsequent G^ Following reoxygenation, these cells progressed into S phase, but the initiation of DNA synthesis was delayed for a period corresponding to at least the duration of normal G₁ and did not appear in a synchronous manner. In fact, cell cycle variability was found to be increased rather than decreased as a result of exposure to hypoxia starting in G₂. We interpret these findings as an indication that important steps in the preparation for initiation of DNA synthesis take place before mitosis. Furthermore, the change in cell cycle duration induced by hypoxia commencing in G₁ is of a nature other than that induced by hypoxia commencing in other parts of the cell cycle.     

Expression of G1 and G2 cyclins measured in individual cells by multiparameter flow cytometry: a new tool in the analysis of the cell cycle

Abstract. Multivariate analysis of the expression of cyclin proteins and DNA content has opened new possibilities for the study of the cell cycle. By virtue of their cell cycle phase specificity, the expression of cyclins may serve, in addition to DNA content, as another marker of a cell's position in the cycle, and provide information about the proliferative potential of cell populations. Several applications of the methodology based on bivariate analysis of DNA content v . expression of B, E and D type cyclins are reviewed: 1 expression of cyclins by individual cells during their progression through the cycle can be studied, using exponentially growing cells without the necessity of cell synchronization or other perturbations of the cycle; 2 cells having the same DNA content but residing in different phases of the cycle (e.g. G₂ diploid v. G₁ tetraploid) can be distinguished; 3 cell transition from G₀ to G₁ and progression through G₁ (e.g. mitogen stimulated lymphocytes) can be assayed; 4 the population of proliferating cells can be distinguished from noncycling cells based on dual cell labelling with a G₁ and G₂ cyclin antibody; 5 cyclin restriction points can serve as additional cell cycle landmarks to map the point of action of antitumour drugs; 6 unscheduled expression of cyclins (e.g. the presence of cyclin B1 during G₁ and S) can be detected in several tumour transformed cell lines, possibly indicating disregulation of the machmery of cell cycle progression. The last finding 6 is of special importance, because such disregulation may be of prognostic consequence in human tumours.     

Unscheduled expression of cyclins D1 and D3 in human tumour cell lines

D-type cyclins are involved in regulation of cell traverse through G₁ primarily by activating the cyclin-dependent kinase 4 (CDK4) and targeting it to the retinoblastoma tumour suppressor protein. There is a vast body of evidence that defective expression of D-type cyclins is associated with tumour development and/or progression. Immunocytochemical detection of D cyclins combined with multiparameter flow cytometry makes it possible to measure the expression of these proteins in individual cells in relation to their cell cycle position without the need for cell synchronization. This approach was used in the present study to compare the cell cycle phase specific expression of cyclins D3 and D1 in human normal proliferating lymphocytes and fibroblasts, respectively, with nine tumour cell lines of different lineage. During exponential, unperturbed growth, expression of cyclin D1 in fibroblasts from donors of different age, or cyclin D3 in lymphocytes, was limited to mid-G₁ cells: Less than 7% of the cells entering S phase or progressing through S and G₂ were cyclin D positive. In contrast, expression of either cyclin D1 or cyclin D3 in tumour cell lines of different lineage was not limited to G₁ phase. Namely, over 80% of the cells in S and G₂+M were cyclin D positive in eight of the nine cell lines studied. The data indicate that while expression of cyclin D1 or D3 in normal cells is discontinuous, occurring transiently in G₁, these proteins are expressed in some tumour lines persistently throughout the cell cycle. This suggests that the partner kinase CDK4 is perpetually active throughout the cell cycle in these tumour lines.     

EFFECTS OF ACTINOMYCIN D AND PUROMYCIN ON THE CELL PROGRESS FROM M TO G1 AND S STAGES IN CULTURED MOUSE LEUKEMIA L5178Y CELLS

Actinomycin D (0.5 μg/ml) did not prevent M stage cells from entering G₁ stage, but blocked their progress from G₁ to S stage. The position of the block was approximately 1.4 hr before S stage or just after the beginning of G₁ stage. Actinomycin D in this concentration also significantly depressed uridine-³H uptake into G₁ stage cells, but did not suppress leucine-³H uptake by M and G₁ cells. This suggests that some proteins may be synthesized in M and G₁ stage cells by messenger RNA left over from the previous cell cycle. However, entry of G₁ cells into S stage would require synthesis of new messenger RNA near the beginning of G₁ stage. Puromycin (10 μg/ml) did not prevent M cells from entering G₁ stage, but blocked their progress from G₁ to S stage. The site of blockage was about 0.7 hr before S stage or in the first two-third of G₁ stage. This might be the site where the cells synthesize new G₁ proteins necessary for entry to S stage.
Comparison of sensitivities of G₁ and G₂ stages to the two antibiotics reveals that the puromycin sensitivity of G₁ cells was similar to that of G₂ cells, but the actinomycin D sensitivity of G₁ was greater than that of G₂ cells.     

Cell cycle related [3H]thymidine uptake and its significance for the incorporation into DNA

Abstract. Cellular uptake of [³H]thymidine ([³H]TdR) and incorporation into DNA of Ehrlich ascites tumour cells were studied in relation to the cell cycle by measuring the activity in the acid-soluble and insoluble parts of the cell material. Cells were synchronized at various stages of the cell cycle using centrifugal elutriation. The degree of synchrony of the various cell fractions was measured by flow-cytofluorometric DNA analysis. From the cellular uptake, the TdR triphosphate (dTTP) concentration of a mean cell in an unseparated cell population was calculated to be 20 × 10^-18 mol/cell. The pool activity of G₁ cells was unmeasurable but rose to maximum values at the border of the G₁-S phase. It decreased again during G₂. The [³H]TdR incorporation into DNA was low during early S phase, reached a maximum value at two-thirds of the S phase and decreased again during late S phase. These changes in DNA synthesis were not due to changes in the dTTP pool being a limiting factor. During maximum DNA synthesis, 10%× min^-1 of the dTTP pool was utilized, at which time the pool size also decreased by about 30%. Changes in pool size during the cell cycle have to be taken into account when the results of incorporation of radioactive TdR into DNA are discussed.     

CELL CYCLE PROPERTIES OF DIFFERENTIATING SPERMATOGONIA IN ADULT SPRAGUE-DAWLEY RATS

The duration of the mitotic cycle and of its components was analysed for each of the six successive generations of differentiating spermatogonia (A₁, A₂, A₃, A4, intermediate and B), using radioautographed whole mounts of seminiferous tubules from testes of adult Sprague-Dawley rats. Cell cycles were determined from two successive waves of per cent labeled metaphases obtained during the period of 81 hr after a single dose of ³H-thymidine. Except for the A₁ spermatogonia, all spermatogonial types (A₂ to B) had similar cell cycle durations of 41-42.5 hr and comparable pre-DNA synthesis phases (G₁) of 11-13 hr. Although the combined duration of DNA synthesis (S) and the post-synthesis phase (G₂) remained identical for all the cell types including A₁, there was a progressive lengthening of the S period at the expense of G₂ during the process of spermatogonial maturation. This change was most marked during the transition from A₁ to A₃ spermatogonia when the S period increased from 14 hr to 21 hr, and the G₂ phase shortened from 13 hr to 7.5 hr. This feature seems to be unique to germ cells and may be associated with an increasing amount of heterochromatin in the nucleus. Excluding the development of type A₁ cells, the entire process of spermatogonial maturation lasted for 208 hr. Combined data on cell cycle times indicated that every 313 hr or 13 days, a new sequence of spermatogonial differentiation was initiated by the A₁ cells. This was equivalent to the duration of one 'cycle' of the seminiferous epithelium as measured by other techniques.     

EFFECTS OF PHYTOCHROME AND BLUE-NEAR ULTRAVIOLET LIGHT-ABSORBING PIGMENT ON DURATION OF COMPONENT PHASES OF THE CELL CYCLE IN ADIANTUM GAMETOPHYTES

Single-celled protonemata of the fern Adiantum capillus-veneris, kept under continuous red light, grew with a very low rate of cell division, and the cell cycle was arrested in the early G₁ phase. Cell division was induced by transferring the protonemata to the dark after various light treatments, and the duration of component phases in the cell cycle was determined by a continuous-labelling technique with 3H-thymidine. Blue light irradiation greatly reduced the duration of the G₁ phase but did not affect that of other phases. The greater the fluence of blue light, the shorter was the duration of G₁ phase was observed. In contrast, a brief exposure of red-light-grown protonemata to far-red light given immediately before the dark incubation showed no effect on the duration of G₁ S and M phases but significantly extended that of the G₂ phase. The effect of far-red light on the G₂ phase was reversed by red light, and the effects of red and far-red light were repeatedly reversible. The progression in the M phase was shown by means of a time-lapse video system to be not at all influenced by any pre-irradiation described above.     

CELL CYCLE COMPARTMENT ANALYSIS OF CHINESE HAMSTER CELLS IN STATIONARY PHASE CULTURES

The distribution of Chinese hamster cells with respect to the compartments of the cell generation cycle was studied in cultures in the stationary phase of growth in two different media. A measure of the state of depletion of the nutrient medium was formulated by defining a quantity termed the nutritive capacity of the medium. This quantity was used to verify that the cessation of cell proliferation is due to nutrient deficiencies and not to density dependent growth inhibition. Cell cultures in stationary phase were diluted into fresh medium and as growth resumed, mitotic index, cumulative mitotic index, label index and viability were measured as a function of time. The distribution of cells with respect to compartments of the cell generation cycle in stationary phase populations was reconstructed from these data. Stationary phase populations of Chinese hamster cells that retained the capacity for renewed growth when diluted into fresh medium were found to be arrested in the G₁ and G₂ portions of the cycle; the relative proportion of these cells in G₁ increased with time in the stationary phase, but the sequence differs in the two media. In early stationary phase, in the less rich medium, more cells are in G₂ than in G₁. Also in this medium a fraction of the population was observed to be synthesizing DNA during stationary phase, but this fraction was not stimulated to renewed growth by dilution into fresh medium.     

The effects of interleukin 4 on the cell cycle of a human B-cell lymphoma line

Abstract. Exposure of Farage, a human B-cell lymphoma line, to IL-4 for 3–11 days led to inhibition of tritiated thymidine ([³H]dT) uptake by the cells. Study of the incorporation of 5-bromodeoxyuridine by Farage cells showed that IL-4 reduced significantly the number of cells in the S phase of the cell cycle and increased the proportion of cells in the G₁ phase. Limiting dilution analysis of proliferation demonstrated that IL-4 decreased the frequency of clone-forming cells by 40%. IL-4 did not reduce the viability of Farage cells. On the contrary, IL-4 diminished the spontaneous death of Farage cells in culture, as determined by pulse chase analysis of cells which were labelled with [³H]dT. Moreover, the pre-treatment of Farage cells with IL-4 prevented their death induced by exposure to a high dose of staurosporine. IL-4 abrogated the staurosporine-induced arrest of cells in the G₂+ M phase and replaced it by accumulation of cells in the G₁ phase. IL-4 protected Farage cells from the radioactive suicide caused by the uptake of [³H]dT by dividing cells. The cytokine failed to prevent the damage to Farage cells exerted by mitomycin C, which affected cellular DNA regardless of the phase of the cell cycle. The data obtained showed that IL-4 inhibited the division of B cells by arresting their progression through the early stages of the cell cycle. This inhibition of the cell efflux from G₁ phase plays an important role in the protection against cell death during further stages of the cell cycle.     

A flow cytometric study of the effect of heat on the kinetics of cell proliferation of Chinese hamster V-79 cells

Abstract. Two methods involving labelling cells with bromodeoxyuridine (BrdUrd) have been used to study by flow cytometry the effect of hyperthermia (43°C for up to 1 h) on Chinese hamster V79 cells. One method involved the use of an antibody to BrdUrd after pulse-labelling the cells either before or at time intervals after treatment. In the second method, the cells were incubated continuously in BrdUrd after heat treatment, and the components of the cell cycle were then visualized by staining with a combination of a bis-bcnzimidazole and ethidium bromide. All three methods showed that heating at 43°C stopped DNA synthesis which, at 37°C, subsequently recovered reaching the normal rate 8–12 h later. The cells in S phase at the time of treatment then progressed to G₂ where they were further delayed. Cells heated in G₁. after the recommencement of synthesis, progressed around the cycle, albeit slower than in unheated cells. The difference between the cells in G₁ and S phases at the time of treatment may account for the greater sensitivity of S phase cells to hyperthermia.     

Monocytic differentiation of HL60 cells induced by potent analogs of vitamin D3 precedes the G1/G0 phase cell cycle block

Abstract. Differentiation of mammalian cells is accompanied by reduced rates of proliferation and an exit from the cell cycle. Human leukemic cells HL60 present a widely used model of neoplastic cell differentiation, and acquire the monocytic phenotype when exposed to analogs of vitamin D₃ (VD₃). The maturation process is accompanied by two blocks in the cell cycle: an arrest in the G₁/G₀ phase, and a recently described G₂+ M block. In this study we have analyzed the traverse of the cell cycle phases of the well-differentiating HL60-G cells exposed to one of ten analogs of VD₃, and compared the cell cycle effects of each compound with its potency as a differentiation-inducing agent. We found that in general there was a good correlation between the effects of these compounds on the cell cycle and on differentiation, but the best cell cycle predictor of differentiation potency was the extent of accumulation of the cells in the G₂ compartment. All analogs induced a marked decrease in the mitotic index, and polynucleation of HL60 cells was produced, especially by compounds which were effective as inducers of differentiation. Time course studies showed that induction of differentiation was accompanied by a transient increase of the proportion of cells in the G₂+ M compartment, but preceded the G₁ to S, and the G₂ compartment blocks. These studies indicate that complex changes in the cell cycle traverse accompany, but do not precede, the acquisition of the monocytic phenotype by HL60 cells.     

Influence of denervation on the regeneration of Pleurodele limbs

Abstract. A cytophotometric study of Feulgen-stained mesenchymal cell nuclei from regeneration blastemas of both innervated and denervated limbs over the 1st 7 days following the midbud stage showed a diminution of the percentage of cells in the S + G₂ phases and a corresponding augmentation of the percentage of cells in the G₀+ G₁ phases. This change, which was temporally correlated with the redifferentiation of the innervated blastemas, was greater in denervated blastemas, even though they do not redifferentiate. From these results, it is concluded that the denervation of midbud blastemas brings about either an extension of the G₁ phase or an exiting from the cell cycle to G₁ (G_0–1), or both phenomena.     

Cytokinetic studies on the switch from glucose to uridine metabolism, and vice versa, of Ehrlich ascites tumour cells in vitro

Abstract. Glucose is normally required as the energy source and for the proliferation of neoplastic cells. For Ehrlich ascites tumour cells, kept under glucose-free culture conditions, this requirement was alleviated by uridine, indicating that the supply of ribose is obligatory for sustaining growth capacity.
In a 96-hr culture experiment with mouse-derived cells, the increase in cell number from cultures supplemented with 5 mM uridine was 50–70%, whilst lactate production was 5% that of controls. An increase in the number of multinucleate cells was observed from cell-smears; DNA histograms indicated the presence of cells with a DNA content higher than 4c and an increased portion of cells in G₂ phase. For precise determination of changes in cell cycle distribution on transfer of cells from glucose-supplemented to glucose-free conditions, the progression of phase-accumulated cells (by centrifugal elutriation) was monitored by DNA distribution analysis; G₂ cells continued the cycle at a rate comparable to controls but were delayed, in the following cycle, predominantly in S and G₂ phases. This was also observed with G₁ cells from a G₁-accumulated fraction in the first cycle.
The addition of glucose to cells kept for some hours in glucose-free, uridine-supplemented medium resulted in an immediate increase in mitotic index (amplification by the colcemid method).
The results are interpreted and support our concept that the delivery of compounds, necessary for normal growth, i.e. hexoses for glycoproteins and glycolipids, are limited as a consequence of the 'metabolic channelling' of pentose from uridine in Ehrlich ascites tumour cells. Therefore, the constantly lowered growth-rate in uridine-supplemented cells observed with long-term culture experiments could reflect an adaption of growth-cycle to these limitations.