The relation between protein accumulation and cell cycle traverse of human NHIK 3025 cells in unbalanced growth

Human NHIK 3025 cells, synchronized by mitotic selection, were given 2 mM thymidine, which inhibited DNA synthesis without reducing the rate of protein accumulation. After removal of the thymidine the cells proceeded towards mitosis and cell division, with an S duration 2 hours shorter than, but a G2 and M duration nearly identical to that of the control cells. If cycloheximide (1.25 m?M) was present together with thymidine, no net protein accumulation took place during the treatment, and the subsequent duration of S, G2, and M was similar to that of the untreated cells. The shortening of S seen after treatment with thymidine alone would therefore indicate that the rate of DNA synthesis depended on the amount of some preaccumulated protein. The postreplicative period in thymidine-treated cells was lengthened by cycloheximide treatment although the protein content had already been doubled. This suggests that proteins required for the traverse of this part of the cell cycle might have to be synthesized after completion of DNA replication. Shortly after removal of thymidine, the rate of protein accumulation declined markedly, indicating the existence of some mechanism for negative control of cell mass. In addition, the daughters of thymidine-treated cells had their cell cycle shortened by 2 hours. As a result, the cells had returned to balanced growth already in the first cell cycle following the induction of unbalanced growth. In conclusion, our experiments suggest that NHIK 3025 cells might require a minimum time in order to traverse the cell cycle, which is independent of cell mass.     

Cell cycle traverse and protein metabolism in human NHIK 3025 cells: the role of anchorage

We have studied the effect of cell anchorage on the human cell line NHIK 3025 in vitro, to see whether the growth regulating effect of cell anchorage primarily affected DNA division cycle or mass growth cycle. It was found that cell to cell anchorage had the same effect on cell cycle progression as anchorage to a solid surface, which indicates that it is anchorage per se and not cell shape that is important for growth control in NHIK 3025 cells. When NHIK 3025 cells were grown without attachment to a solid surface, both G1 and cell cycle duration was prolonged by 6 h, which means that the prolonged cell cycle was due to a prolonged G1. During the first part of the cell cycle the rate of protein synthesis and degradation was constant, and at the same level in cells grown with and without attachment. This means that the prolonged G1 was not due to a reduced protein accumulation or mass growth. Towards the end of the cell cycle protein accumulation was reduced. This effect was either due to a size control before cell division or a secondary effect of the prolonged G1. We therefore conclude that cell anchorage as a growth regulator primarily affects the DNA/cell division cycle.     

Effect of serum step-down on protein metabolism and proliferation kinetics of NHIK 3025 cells

Human NHIK 3025 cells growing exponentially in 30% or 3% serum had population doubling times of 19.1 and 27.6 hours, respectively. These values were equal to the calculated protein doubling times (17.6 and 26.5 hours, respectively), showing that the cells were in balanced growth at both serum concentrations. Stepdown from 30% to 3% serum reduced the rate of protein synthesis within 1–2 hours, from 5.7% hour to 4.3% hour, while the rate of protein degradation was unchanged (1.7%/hour). In cells synchronized by mitotic selection from an exponentially growing population, the median cell cycle durations in 30% and 3% serum were 17.2 and 23.6 hours, respectively, which were also in good agreement with the protein doubling times. The median G₁ durations were 7.1 and 9.6 hours, respectively. Thus the duration of G₁ relative to the total cell cycle duration was the same in the two cases. Complete removal of serum for a period of 3 hours resulted in a 3-hour prolongation of the cell cycle regardless of the time after mitotic selection at which the serum was removed. For synchronized cells, the rate of entry into both the S phase and into the subsequent cell cycle were reduced in 3% serum as compared to 30% serum, the former rate being significantly greater than the latter at both serum concentrations. Our results thus indicate that these cells are continuously dependent upon serum throughout the entire cell cycle.     

The role of protein metabolism in glucocorticoid-lnduced prolongation of G1 phase in human NHIK 3025 cells

It has previously been found that human NHIK 3025 cells have a glucocortiocoid-sensitive restriction point in mid-G1 phase of the cell cycle. When these cells were synchronized by mitotic selection and exposed to dexamethasone before the restriction point, G1 phase was prolonged whereas the rest of the cell cycle was unperturbed by the hormone. These observations were confirmed by flowcytometric mesurements of synchronized cells in the present study. Cells that received dexamethasone (10^?6 M) just after mitotic selection had a 4 hour prolongation of both G1 and the total cell cycle. However, the general rates of both protein synthesis and protein degradation were found not to be altered by the hormone, i.e., the rate of protein accumulation in dexamethasone exposed cells was equal to that of control cells. Dexamethasone exposed NHIK 3025 cells were found to be larger than control cells at the time of cell division. This is a direct consequence of a prolonged cell cycle duration with no change in general protein metabolism. It thus appears that the dexamethasone-induced prolongation of G1 phase is the result of a steroid-regulated G1 specific process(es) leading toward DNA replication, a process that does not alter general protein accumulation.     

Doubling of cell mass is not necessary in order to achieve cell division in cultured human cells

When exponentially growing NHIK 3025 cells were shifted from medium containing 30% serum to medium containing 0.03% serum the rate of net protein accumulation was reduced due to both a reduction in the rate of protein synthesis and an increase in the rate of protein degradation. This change in growth conditions increased the protein doubling time from 18 to 140 h. The cell cycle duration of cells synchronized by mitotic selection was, however, only increased from 17 to 26 h by this treatment. Therefore, when the cells divide by the end of the first cell cycle following synchronization, the cells shifted to 0.03% serum contained far less protein than those growing continuously in 30% serum. Hence, the attainment of a critical cell mass is probably not controlling cell division for cells growing in a balanced state.     

DNA synthesis in polyoma virus infection. III. Mechanism of inhibition of viral DNA replication by cycloheximide.

The formation of viral DNA was inhibited in polyoma virus-infected cells in which protein synthesis had been blocked by cycloheximide. The present studies show the following. (i) The pool of replicating viral DNA molecules was reduced in cycloheximide-treated cells by an amount consistent with inhibition of [3-H]thymidine incorporation into viral DNA, whereas the rate of turnover of the replicating population was not affected. (ii) The rate of conversion of replicating molecules into closed-circular DNA was not affected by cycloheximide. (iii) The rate of elongation of nascent viral DNA fragments into strands of unit genome length was unaffected by cycloheximide. It is concluded that viral DNA synthesis is inhibited in the absence of protein synthesis exclusively at the level of initiation of new rounds of genome replication. Replicating molecules already initiated at the time of addition of cycloheximide matured into progeny closed-circular DNA at a normal rate.     

Progress through G1 and S in relation to net protein accumulation in human NHIK 3025 cells

We have investigated whether human NHIK 3025 cells are dependent upon a net increase in cellular protein content in order to traverse G1 and S. The increase in DNA and protein content was studied by means of two-parameter flow cytometry using populations of cells synchronized by mitotic selection. By adding 1 μM cycloheximide to the medium protein synthesis was partially inhibited, resulting in negligible net accumulation of protein. The cells were able to enter S and progress through S under such conditions. The latter was the case whether the cells had been accumulating protein during G1 or not. The results further indicate that the larger cells enter S earlier and traverse S at a higher rate than the smaller cells. Our conclusion is that net accumulation of protein does not seem to be a prerequisite for traverse through G1 and S, i.e. DNA replication may be dissociated from the general growth of cell mass.     

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.     

Cell Kinetic Characteristics In Different Parts of Multicellular Spheroids of Human Origin

The growth fraction, the cell cycle time, and the duration of the individual cell cycle phases were determined as a function of distance from the surface of multicellular spheroids of the human cell line NHIK 3025. the techniques employed were percentage of labelled mitoses and labelling index measurements after autoradiography and flow cytometric measurements of DNA histograms. to separate cell populations from the different parts of the spheroid, fractionated trypsinization was employed. The results were compared with corresponding values in NHIK 3025 cell populations grown as monolayer cultures. While practically all cells in exponentially growing monolayer populations are proliferating, the growth fraction was between 0.6 and 0.7 in the outer parts of the spheroid. the inner region was mainly occupied by a necrotic mass. the proliferating fraction of the recognizable cells in the inner region was slightly below 0.5. the mean cell cycle time of NHIK 3025 cells in monolayer culture is 18 hr. the mean cell cycle time of proliferating cells in the periphery of the spheroid was 30 hr, compared to 41 hr in the inner region (150 μm from the spheroid surface). All phases of the cell cycle were prolonged compared to populations of exponentially growing monolayer cells. Within each part of the spheroid the distribution of cell cycle times was considerably broadened compared with monolayer populations.     

Retinoic acid induces a specific membrane glycoprotein in human epithelial cell lines

Retinoic acid (RA) inhibits growth, increases the cytokeratin content, and alters the cytoskeleton of the human cervical cell line NHIK 3025. Using RA-treated NHIK 3025 cells as immunogen we prepared murine monoclonal antibodies (IgG1) which recognized an RA-induced cell-surface antigen which could not be detected in untreated NHIK 3025 cells. Analysis of the Triton soluble proteins by SDS-gel electrophoresis and immunoblotting revealed that the cell-surface antigen is a 140-kDa glycoprotein (gp140). gp140 was also shown to be induced by RA in HeLa S3 cells and constitutively expressed in the human trophoblast cell line BeWo. gp140 was also detected in other human epithelial cell lines, but not in human hematopoietic cells. Expression of gp140 was induced in HeLa S3 cells by nanomolar concentrations of RA, and in NHIK 3025 cells by micromolar amounts (1-10 microM). The glycoprotein was detectable 3-6 h following exposure to RA and its expression was reversible upon removal of RA from the medium. Our results indicate that gp140 is a newly identified RA-inducible epithelial membrane glycoprotein which may represent a phenotypic differentiation marker for epithelial cells.     

The origin of variability in cell cycle durations of NHIK 3025 cells

The origin of cell cycle variability was investigated in NHIK 3025 cells synchronized by mitotic selection from an exponentially growing population. The variability in G1 durations was measured by flow cytometric analysis of the fraction of cells in G1 as a function of time after mitotic selection. Immediately before the first cells entered S, medium containing 2.0 mM thymidine was added to the cells, and removed when all the cells had reached S. Since the cells had approximately the same DNA content upon removal of the thymidine, the variability in the durations of S+G2+M was measured by counting the fraction of undivided cells as a function of time after removing the thymidine. Such a thymidine treatment did not affect the naturally occurring variability in cell cycle durations generated after the start of S. The results indicate that the cell cycle variability of NHIK 3025 cells can be adequately described by a cell cycle model consisting of at least two compartments, which the cells leave according to first order kinetics. The model accounts for the initial shoulder of the curve representing the fraction of undivided cells as a function of time after mitotic selection. Furthermore, it accounts for the reduction in the rate of entry into the subsequent cell cycle compared to the rate of entry into S. Both rate constants were equally reduced after serum stepdown.     

Cell cycle-specific glucocorticoid growth regulation of a human cell line (NHIK 3025)

It has been reported that the human cell line NHIK 3025 has a specific cytoplasmic glucocorticoid receptor. When these cells were exposed to glucocorticoids, the cell cycle time was prolonged. Cells, synchronized by mitotic selection, were subjected to the synthetic glucocorticoid dexamethasone throughout the cell cycle. Only cells exposed in the first half of G1 phase had a lengthened cell cycle time. Most of the prolongation was also located within the G1 phase. The dexamethasone growth inhibition was reversible and could be detected only in the cell cycle where the cells were exposed to the steroid. DNA-histograms of asynchronous cells were recorded by flowcytometry at various times after steroid exposure. These histograms also showed G1 phase sensitivity and G1 phase prolongation after exposure to dexamethasone. Our results thus indicate that these cells have a dexamethasone-sensitive restriction point in mid-G1 phase of the cell cycle.     

Cycloheximide induces accumulation of vasoactive intestinal peptide (VIP) binding sites at the cell surface of a human colonic adenocarcinoma cell line (HT29-D4). Evidence for the presence of an intracellular pool of VIP receptors

Incubation of monolayers of HT29-D4 cells (a clone of the human colonic adenocarcinoma cell line HT29) in the presence of 17.5 microM cycloheximide resulted in an increase in the number of vasoactive intestinal peptide (VIP) binding sites at the cell surface without any change in the affinity of receptor for its ligand. The increase in 125I-VIP-binding capacity was dose-dependent between 0.35 microM and 17.5 microM cycloheximide and was correlated with the inhibition of protein biosynthesis. At higher concentrations of drug (17.5-100 microM) a plateau corresponding to a twofold increase in VIP-binding capacity was reached independently of the extent of protein synthesis inhibition. We found that VIP receptors of HT29-D4 cells with such an enhanced binding capacity behaved like those of control cells with respect to receptor internalization and recycling (i.e. the cycle of occupied receptors was insensitive to cycloheximide). After inactivation of 90% of cell-surface VIP receptors by alpha-chymotrypsin, we observed a biphasic kinetic of reappearance of VIP-binding sites. 40% of VIP-binding sites reappeared very quickly (less than 5 min) and 100% within 17 h. The fast recovery of VIP receptors was probably due to the deployment of new binding sites from an intracellular pool. The rate and extent of recovery of these receptors were similar in control cells and in cycloheximide-treated cells. However, the slow recovery was inhibited in cycloheximide-treated cells probably because a pool of immature receptors was depleted by the drug before the alpha-chymotrypsin treatment. Our data are consistent with the existence of two different intracellular pathways of occupied and unoccupied VIP receptors.     

Cell cycle characteristics of synchronized and asynchronous populations of human cells and effect of cooling of selected mitotic cells.

The method of synchronizing cells by means of mitotic selection has been adapted to the human line NHIK 3025. Increase in cell number as a function of time in asynchronous and synchronous populations was studied as well as mitotic index as a function of time after selection of synchronized populations. Phase durations of the cell cycle of synchronous populations were determined by 3H-thymidine incorporation and scintillation counting. The relative phase durations of exponentially growing asynchronous populations were determined by mathematical analysis of DNA-histograms recorded by flow cytofluorimetry. Both the generation time and the various phase durations of the cell cycle were found to be the same in asynchronous and synchronous populations. It was found that NHIK 3025 cells are damaged by cooling to 4 and 0 degrees C so that cooling of selected cells in order to increase the yield would reduce the quality of the synchronized populations.     

CELL CYCLE CHARACTERISTICS OF SYNCHRONIZED AND ASYNCHRONOUS POPULATIONS OF HUMAN CELLS AND EFFECT OF COOLING OF SELECTED MITOTIC CELLS

The method of synchronizing cells by means of mitotic selection has been adapted to the human line NHIK 3025. Increase in cell number as a function of time in asynchronous and synchronous populations was studied as well as mitotic index as a function of time after selection of synchronized populations. Phase durations of the cell cycle of synchronous populations were determined by ³ H-thymidine incorporation and scintillation counting. The relative phase durations of exponentially growing asynchronous populations were determined by mathematical analysis of DNA-histograms recorded by flow cytofluorimetry. Both the generation time and the various phase durations of the cell cycle were found to be the same in asynchronous and synchronous populations. It was found that NHIK 3025 cells are damaged by cooling to 4 and 0°C so that cooling of selected cells in order to increase the yield would reduce the quality of the synchronized populations.     

Inhibition of arbovirus assembly by cycloheximide

Addition of cycloheximide (100 μg/ml) to cultures of chick cells infected with Semliki Forest virus (SFV) halted subsequent increase in virus titers. When added after 4 hr of infection, the drug had no effect on the rate of viral ribonucleic acid (RNA) synthesis, although marked inhibition of protein synthesis was seen. All of the previously identified forms of SFV RNA were seen in the drug-treated cells at higher concentrations than were present in untreated controls. The latter observation appeared to result from a failure to form viral “cores” or nucleocapsids in the cycloheximide-treated cells, resulting in sequestration of viral RNA intracellularly. The failure to form new virus cores was correlated with the failure of type II cytopathic vacuoles to appear in thin sections. Virus budding from the cell surface and the formation of type I cytopathic vacuoles persisted in cycloheximide-treated cells. The cellular pool of the major protein present in the virus core appeared to be small. None of this protein was found in a free pool in cytoplasm. The results indicated that, in the presence of cycloheximide, virus assembly was impaired because of the small size of the cellular pool of the major protein required for virus core formation.     

Hypoxia-induced irreversible S-phase arrest involves down-regulation of cyclin A

We have studied hypoxia-induced cell cycle arrest in human cells where the retinoblastoma tumour suppressor protein (pRB) is either functional (T-47D cells) or abrogated by expression of the HPV18 E7 oncoprotein (NHIK 3025 cells). All cells in S phase are immediately arrested upon exposure to extreme hypoxia. During an 18-h extreme hypoxia regime, the cyclin A protein level is down-regulated in cells of both types when in S-phase, and, as we have previously shown, pRB re-binds in the nuclei of all T-47D cells (Amellem et al. 1996). Hence, pRB is not necessary for the down-regulation of cyclin A during hypoxia. However, our findings indicate that re-oxygenation cannot release pRB from its nuclear binding following this prolonged exposure. The result is permanent S-phase arrest even after re-oxygenation, and this is correlated with a complete and permanent down-regulation of cyclin A in the pRB functional T-47D cells. In contrast, both cell cycle arrest and cyclin A down-regulation in S phase are reversed upon re-oxygenation in non-pRB-functional NHIK 3025 cells after prolonged exposure to extreme hypoxia. Our results indicate that pRB is involved in permanent S-phase arrest and down-regulation of cyclin A after extreme hypoxia.     

Inactivation of protein synthesis stimulating activity in serum by cells

When Ehrlich ascites cells were cultivated in serum-free media their cellular protein synthetic rate declined to a new steady-state level and the cells stopped multiplying. On addition of serum the cellular protein synthetic rate increased to the level before serum starvation and cells resumed multiplication. The activity in serum stimulating protein synthesis was inactivated on incubation with cells. At cell concentrations of the usual culture conditions this inactivation took several hours; at very high cell concentrations it was complete in ten minutes. Serum-starved cells inactivated low serum (2%–6%) media in the same length of time. Studies of inactivation of high serum media demonstrated that cells had a limted capacity to inactivate. Cells grown in 10% serum were unable to inactivate. Inactivation was not due to accumulation in the medium of either low molecular or macromolecular cell products. Inactivation was strongly inhibited at 4° or by treatment of cells with fluoride or cycloheximide (long exposure): less inhibited by treatment with 2-deoxyglucose or glutaraldehyde; and slightly inhibited by treatment with cyanide or cycloheximide (short exposure). Inactivating ability was unaffected by trypsinization. These findings are best explained by the hypothesis that cells take up the serum activity by endocytosis.     

Centrosome duplication continues in cycloheximide-treated Xenopus blastulae in the absence of a detectable cell cycle

Cycloheximide (500 micrograms/ml) rapidly arrests cleavage, spindle assembly, and cycles of an M-phase-specific histone kinase in early Xenopus blastulae. 2 h after cycloheximide addition, most cells contained two microtubule asters radiating from perinuclear microtubule organizing centers (MTOCs). In contrast, blastomeres treated with cycloheximide for longer periods (3-6 h) contained numerous microtubule asters and MTOCs. Immunofluorescence with an anticentrosome serum and EM demonstrated that the MTOCs in cycloheximide-treated cells were typical centrosomes, containing centrioles and pericentriolar material. We conclude that centrosome duplication continues in cycloheximide-treated Xenopus blastulae in the absence of a detectable cell cycle. In addition, these observations suggest that Xenopus embryos contain sufficient material to assemble 1,000-2,000 centrosomes in the absence of normal protein synthesis.     

Requirement of protein synthesis in the initiation of meiosis and other nuclear changes in conjugation of Blepharisma.

In conjugation of Blepharismajaponicum, cell contact between complementary mating types induces meiosis and other nuclear changes. How long the cells must be in contact in order to be induced to undergo these nuclear changes (activated) can be ascertained by surgically separating the united cells at different times after the onset of cell union and then examining the occurrence of the nuclear changes. Applying this technique to cycloheximide-treated cells, we investigated the role of protein synthesis in the activation. Cycloheximide was used at the concentration which was found to inhibit most incorporation of amino acid into protein in this ciliate. Newly formed conjugant pairs were incubated with and without cycloheximide, washed free of the inhibitor and surgically separated. Although untreated controls were activated in 1.8 h after cell-cell contact, no activation was observed in cycloheximide-treated cells after 5 h of contact. Removal of cycloheximide from the paired cells resulted in an activation delayed by the interval of exposure time to the inhibitor. If the pairs were first incubated in normal medium and then exposed to cycloheximide, operated, activated cells appeared and increased very slowly (activation rate, about $\text{1}\text{10}$ of the control). Protein synthesis is therefore required for the initiation of meiosis and other nuclear changes. We propose that heterotypic cell union induces and maintains the synthesis of a protein, whose accumulation to a certain threshold is required for activation.