Effect of cell trypsinization on nuclear proteins of WI-38 fibroblasts in culture.

When resting confluent monolayers of WI-38 fibrolasts are trypsinized and replated at a lower density they are stimulated to proliferate again with an interval of 18 hours between replating and the onset of DNA synthesis. Trypsinization of resting cells causes a 40% loss of nuclear proteins as well as of cytoplasmic proteins. The amount of nuclear proteins remains low for the first six hours after the cells have been replated and then it increases rapidly, reaching the same level of non-trypsinized resting cells by ten hours after plating. The proteins that are lost from the nucleus immediately after trypsinization are chromatin-associated proteins and most of them are non-histone chromosomal proteins, although a modest loss of histones cannot be ruled out. The loss of non-histone chromosomal proteins from cells that have been trypsinized causes changes in the structure of chromatin that can be detected by circular dichroism and by viscosity measurements. These results show that cell trypsinization causes an extensive loss of proteins from chromatin and that the loss is restored only several hours after the cells have been replated at a lower density.     

Analysis of the growth factor requirements for stimulation of WI-38 cells after extended periods of density-dependent growth arrest

When cultures of WI-38 human diploid fibroblasts reach high cell densities, they cease to proliferate and enter a viable state of quiescence. WI-38 cells can remain in this quiescent state for long periods of time; however, the longer the cells remain growth arrested, the more time they require to leave G0, progress through G1, and enter S after stimulation with fresh serum. The experiments presented here compare the response of long-term quiescent WI-38 cells (stimulated 26 days after plating) and short-term quiescent WI-38 cells (stimulated 12 days after plating) to treatment with a variety of individual purified growth factors instead of whole serum. Our results show that the qualitative and quantitative growth factor requirements necessary to stimulate G1 progression and entry into S were the same for both short- and long-term quiescent WI-38 cells, in that the same defined medium (supplemented with epidermal growth factor [EGF], recombinant human insulin-like growth factor 1 [IGF-1], and dexamethasone [DEX]) stimulated both populations of cells to proliferate with the same kinetics and to the same extent as serum. However, the long-term quiescent WI-38 cells were found to exhibit a difference in the time during which either serum or these individual growth factors were required to be present during the prereplicative period. We believe that this difference may be the cause of the prolongation of the prereplicative phase after stimulation of long-term density-arrested WI-38 cells.     

Tyrosine protein kinase expression in long-term quiescent WI-38 cells following growth factor simulation

We have used the WI-38 cell long-term quiescent model system to study the regulation of cell cycle progression at the molecular level. By modulating the length of time that WI-38 cells are density arrested, it is possible to proportionately alter the length of the prereplicative or G-1 phase which the cell traverses after growth factor stimulation in preparation for entry into DNA synthesis. Stimulation of long-and short-term density arrested WI-38 cells with different growth factors or higher concentrations of individual growth factors does not alter the time required by long-term cells to enter S after stimulation. However, the time during the prereplicative period for which these growth factors are needed is different. Long-term quiescent WI-38 cells require EGF to traverse the G-0/G-1 border but do not need and apparently cannot respond to IGF-1 during the first 10 h after EGF stimulation, the length of the prolongation of the prereplicative phase. This suggests that EGF stimulation of long-term quiescent WI-38 cells initiates a series of molecular events which make these cells “competent” to respond to the “progression” growth factor, IGF-1. In light of the well-established role of protein tyrosine kinases in signal transduction, we set out to identify, clone, and analyze the expression of receptor and non-receptor tyrosine kinases which potentially could play a role during the prolongation of the prereplicative phase in making the long-term quiescent WI-38 cells competent to respond to IGF-1. We obtained 49 clones representing 11 different receptor and non-receptor type protein tyrosine kinases. Analysis of expression of these clones revealed a variety of different patterns of expression. However, the most striking pattern was exhibited by IGF-1 receptor. Our results suggest that induction of IGF-1 receptor mRNA by EGF may be an important event in the establishment of competence by EGF in long-term density arrested WI-38 cells. © 1995 Wiley-Liss, Inc.     

Changes in the G0 state of WI-38 fibroblasts at different times after confluence

Some events in the prereplicative phase of WI-38 human diploid fibroblasts stimulated to proliferate are found to be a function of the length of time the cells have been quiescent. At 5 days after plating, when the cells first become confluent, the prereplicative phase upon stimulation by a nutritional change is relatively short, DNA synthesis begins at 8 h after stimulation, and there is no increase in chromatin template activity. At 9 days after plating the prereplicative phase of stimulated cells is lengthened to 14 h and there is an increase in chromatin template activity within 1 h of stimulation. Finally, in 18-day cells, the prereplicative phase is lengthened even further to 20 h, and there is a lag after stimulation before the increase in chromatin template activity. It is proposed that confluent WI-38 cells initially arrest in G 1, subsequently pass into G 0, and continue to go deeper into G 0 as they remain quiescent.     

Properties of the genome in normal and SV-40 transformed WI-38 human diploid fibroblasts. III. Turnover of nonhisone chromosomal proteins and their phosphate groups.

The turnover of nonhistone chromosomal proteins and their phosphate groups was compared in normal and in SV-40 virus transformed WI-38 human diploid fibroblasts. Cells were pulse labelled with tryptophan-³H and ³²P for 30 minutes and the specific activities of tryptophan-³H and ³²P in the various molecular weight classes of nonhistone chromosomal proteins were determined during the first four hours following termination of labelling. While a rapid turnover of high molecular weight nonhistone polypeptides (142, 000 to 200, 000 Daltons) is evident after one hour in SV_40 transformed cells, the specific activities of these nonhistone chromosomal polypeptides are not significantly decreased in normal cells. In contrast, a rapid turnover of low molecular weight (30, 000 to 51, 000 Daltons) nonhistone chromosomal proteins occurs during the first hour in normal WI-38 cells with no corresponding decrease in the specific activities of these proteins in SV-40 transformed cells. There is no apparent net turnover of phosphate groups on nonhistone chromosomal proteins in either normal or SV-40 transformed cells four hours following pulse labelling. Rather, during the first four hours significant fluctuations are observed in the ³²P specific activities of defined molecular weight fractions. Taken together with previous reports of differences in the composition, synthesis and phosphorylation of nonhistone chromosomal proteins in normal and SV-40 transformed human diploid cells the present results further indicate the complex nature of the alterations in these proteins which accompany viral transformation.     

Role of nonhistone chromosomal proteins in determining circular dichroism spectra of chromatin.

Complexing of histone proteins, from WI-38 cells with pure DNA from WI-38 cells, causes a marked decrease in the amplitude of the positive ellipticity band and a red shift in circular dichroism spectra in the 250–300 nm region. Total nonhistone chromosomal proteins from WI-38 cells (without histones) cause an analogous effect, but of significantly reduced magnitude. However, the two effects are not additive, because, when DNA is complexed with both histones and nonhistones, the amplitude of the positive ellipticity band has an intermediate value, between the histone-DNA complex and the nonhistone-DNA complex. Removal of certain nonhistone proteins from chromatin of WI-38 cells, by extraction with 0.25–0.35 m NaCl, causes a decrease in the positive circular dichroism band in the 250–300 nm region. Removal of histones and other nonhistone proteins from chromatin by extraction with 0.75 and 1.5 m NaCl causes a strong increase in positive ellipticity. This suggests the existence of modest but definite effects of nonhistone proteins in determining DNA conformation in native chromatin. Taken as a whole, nonhistone chromosomal proteins have a weaker but analogous effect to that of histones, while the nonhistone proteins extractable with 0.25–0.35 m NaCl have an opposite effect.     

Inhibition of cellular transition from G1-resting to G1-prereplicative phase by aminonucleoside of puromycin.

Human embryonic lung fibroblasts (IMR-90 and WI-38) were arrested in the G1 phase of the cell cycle by serum deprivation and high population density. Within 1 hr after the addition of medium containing fresh serum, these cells showed an increase in rRNA synthesis. The inclusion of 100 micrograms per ml aminonucleoside of puromycin (AMS) in the fresh medium eliminated the serum stimulation of rRNA synthesis and prevented the cells from making the G1-resting phase to G1-prereplicative phase transition. AMS also prevented the synthesis of HnRNA normally found within 10 hr after serum stimulation. Serum-stimulated RNA synthesis in starved, SV-40 transformed fibroblasts (WI-38-VA-13 cells) was inhibited, but not completely prevented, by AMS indicating that transformed cells may produce specific RNA's that are not AMS-sensitive and that may be responsible for the failure of transformed cells to be arrested in G1.     

Effect of vitamin A on epithelial morphogenesis in vitro

Quiescent confluent monolayers of WI-38 human diploid fibroblasts and of 3T6 mouse fibroblasts were stimulated to proliferate by nutritional changes. WI-38 cells had a stringent requirement for serum factor(s) but 3T6 did not require serum in order to proliferate again. In both cell lines there was an early increase in the synthesis of non-histone chromosomal proteins shortly after stimulation of cellular proliferation and this increase was linearly correlated to the number of cells entering the S phase several hours later. Only WI-38 diploid fibroblasts, however, showed an early increase in chromatin template activity 1 h after stimulation of cellular proliferation, while chromatin template activity in 3T6 cells remained unchanged. It is suggested that the activation of gene function represents a critical step for the passage of WI-38 cells in the G0 resting phase to the G1 phase of the cell cycle. It is also suggested that 3T6 cells are unable to enter or stay in a G0 phase but can be arrested predominantly in the G1 phase by nutritional deficit, probably amino acid starvation.     

Effects of prolonged quiescence on neuclei and chromatin of WI-38 fibroblasts.

DNA synthesis and cell division are markedly reduced in confluent mono-layers of WI-38 diploid fibroblasts, but resume again if the depleted medium is replaced by fresh medium containing 10% fetal calf serum. If the cells are kept quiescent for prolonged periods of time after confluence (1 or 2 weeks), the fraction of cells that can be stimulated to proliferate by fresh serum decreases and the length of the prereplicative phase increases. The template activity of isolated nuclei decreases with increasing time of quiescence, and parallel changes occur in chromatin as evidenced by circular dichroism spectra and capacity to bind the intercalating dye, ethidium bromide. When WI-38 cells are stimulated to proliferate after prolonged quiescence, the increase in template activity of nuclei is delayed by several hours in comparison to cells stimulated after short periods of quiescence. Two distinct steps, both requiring serum, can be identified in the prereplicative phase of cells stimulated to proliferative after prolonged quiescence. We interpret the results as indicating that, during prolonged quiescence, WI-38 fibroblasts go into a deeper GO state from which they can be rescued only after prolonged stimulation. In this respect, prolonged quiescence may bear some resemblance to the process of aging.     

Transcriptional activity and chromatin structural changes in a temperature-sensitive mutant of BHK cells blocked in early G1.

AF8, a temperature-sensitive mutant of BHK $\text{21}\text{13}$ cells, has been shown to arrest at the non-permissive temperature in the G1 phase of the cell cycle. When AF8 cells are released from density-dependent arrest of growth by trypsinization and replating at lower density, 60–80% of the cells enter DNA synthesis and divide at the permissive temperature (33 °C), while only 20% enter DNA synthesis at the non-permissive temperature (39.5 °C). The temperature-sensitive block has been localized 4 to 8 h before the onset of DNA synthesis which begins at 12 h after stimulation. Two biochemical events of the prereplicative phase have been temporally related to this temperature-sensitive block. RNA synthesis as measured in isolated nuclei increases initially at both temperatures, then levels off and declines to control levels at 39.5 °C while continuing to increase at 33 °C. Parallel changes are found in circular dichroism spectra and ethidium bromide binding capacity of isolated chromatin. The results suggest that these biochemical changes are involved in the regulation of the prereplicative phase and the subsequent entrance of cells into DNA synthesis.     

Relationship between cell proliferation, chromatin template activity and accumulation of nuclear proteins

Trypsinization of confluent monolayers of WI-38 cells causes an extensive loss of nuclear proteins. The loss of nuclear proteins is restored only several hours after the cells have been replated at a lower density in 10% serum. When trypsinized fibroblasts are replated at a lower density in 10% serum, there is also a sustained progressive leading to DNA synthesis and cell division. If 0.3% serum is used instead of 10%, there is a modest increase in nuclear template activity, but not accumulation of nuclear proteins and no DNA synthesis or cell division.     

Inhibition of cellular transition from G1-resting to G1-prereplicative phase by aminonucleoside or puromycin

Summary Human embryonic lung fibroblasts (IMR-90 and WI-38) were arrested in the G₁ phase of the cell cycle by serum deprivation and high population density. Within 1 hr after the addition of medium containing fresh serum, these cells showed an increase in rRNA synthesis. The inclusion of 100 μg per ml aminonucleoside of puromycin (AMS) in the fresh medium eliminated the serum stimulation of rRNA synthesis and prevented the cells from making the G₁-resting phase to G₁-prereplicative phase transition. AMS also prevented the synthesis of HnRNA normally found within 10 hr after serum stimulation. Serum-stimulated RNA synthesis in starved, SV-40 transformed fibroblasts (WI-38-VA-13 cells) was inhibited, but not completely prevented, by AMS indicating that transformed cells may produce specific RNA's that are not AMS-sensitive and that may be responsible for the failure of transformed cells to be arrested in G₁. This work was supported by PHS Research Grant CA19750-02 from the National Cancer Institute. These results were reported previously in a preliminary form (7).     

Changes in membrane transport function in G0 and G1 cells

Confluent quiescent monolayers of aneuploid and euploid cells in culture can be stimulated to proliferate by appropriate nutritional changes. In confluent monolayers of WI-38 human diploid fibroblasts the uptake of cycloleucine is increased three hours after these cells are stimulated to proliferate by a change of medium plus 10% serum. No changes in the uptake of cycloleucine are observed in logarithmically-growing WI-38 cells exposed to fresh medium plus 10% serum, or in WI-38 confluent monolayers in which the conditioned medium has been replaced by fresh medium with 0.3% serum (a change that does not cause stimulation of cellular proliferation in WI-38 cells). In 3T6 cells in the stationary phase stimulated to proliferate by nutritional changes, there is a prompt increase in the uptake of cycloleucine, within one hour after stimulation of cell proliferation. Similar results were obtained with stationary 2RA cells which are SV-40 transformed WI-38 fibroblasts. In addition, chromatin template activity which is known to increase in the early stages after stimulation of confluent WI-38 cells, was unchanged in confluent 3T6 or 2RA cells stimulated to proliferate. These results show that at least two of the very early biochemical events occurring in response to stimulation of cell proliferation are different in WI-38 diploid cells and in aneuploid 2RA or 3T6 cells. It is proposed that WI-38 cells in the stationary phase are arrested in the G₀ phase of the cell cycle, while 2RA and 3T6 cells are arrested in the G₁ phase.     

Early changes in the synthesis of acidic nuclear proteins in human diploid fibroblasts stimulated to synthesize DNA by changing the medium

When resting WI-38 cells in a confluent monolayer were stimulated to proliferate by changing the medium, the incorporation of leucine-³H into nuclear acidic proteins was promptly stimulated, although its incorporation into total cellular proteins was unchanged or even decreased. Three fractions, all acidic by aminoacid analysis, were extracted from the nuclei: (1) ribonucleoproteins (RNP); (2) a fraction extractable with 0.15 M NaC1; and (3) a fraction tenaciously bound to the insoluble residue (residual fraction). A first increase occurred between one and three hours after stimulation in all three fractions. The synthesis of NaCl-soluble proteins then returned to control levels, while the synthesis of residual and RNP proteins remained high between 6 and 12 hours and increased even further at 18 hours, the peak of DNA synthesis. Pulse chase experiments indicated that the proteins synthesized in the first hour after stimulation have a turnover time of less than four hours, while the same fractions in non-proliferating cells were stable for at least 12 hours. 2-mercapto-1-(β-4-pyridethyl) benzimidazole, when added at the same time as the fresh medium, produced an inhibition of the increase in nuclear protein synthesis at one hour, but, if added at five hours after stimulation, it did not inhibit the increase in nuclear protein synthesis occurring at six hours. Actinomycin D (0.01 μg/ml) inhibited both the stimulation of DNA synthesis and the increases in nuclear acidic protein synthesis occurring at one and six hours after stimulation. These results seem to indicate that the serum factors responsible for the stimulation of WI-38 cells, after binding to cells, induce an early synthesis of acidic nuclear proteins which is sensitive to very low doses of actinomycin D. In turn, the newly synthesized proteins could in some way activate in the nuclei the genes that control DNA synthesis and cell division.     

Effect of cyclic AMP on chromatin-bound protein kinases in WI-38 fibroblasts stimulated to proliferate.

When resting confluent monolayers of WI-38 fibroblasts are stimulated to proliferate by serum, DNA synthesis begins to increase between 15-18 h after stimulation. Chromatin-bound protein kinase activity increases in stimulated cells within 1 h after the nutritional change, concomitant with an increase in the template activity of nuclear chromatin. Addition of dibutyryl 3' : 5'-cyclic adenosine monophosphate (dibutyryl cyclic) AMP to the stimulating medium inhibits the entrance of cells into S phase, but only if dibutyryl cyclic AMP (5-10(-4) M) is added before the onset of DNA synthesis. The increases in chromatin template activity and in the chromatin-bound kinase activity are not inhibited by dibutyryl cyclic AMP in the early hours after stimulation, but are completely inhibited after the 5th hour from the nutritional change. This seems to indicate that in stimulated WI-38 cells, dibutyryl cyclic AMP exerts its inhibitory action somewhere between 5 and 12 h after stimulation. A number of protein kinase activities were extracted from chromatin with 0.3 M NaCl and partially resolved on a phosphocellulose column. Two distinct peaks of protein kinase activity appeared to be markedly increased in WI-38 cells 6 h after serum stimulation. Both peaks of increased activity were inhibited by dibutyryl cyclic AMP in vivo. Adenosine, sodium butyrate and adenosine 5'-monophosphate (AMP) do not inhibit the increase in DNA synthesis nor the increase in protein kinase activity. The results suggest that stimulation of cell proliferation in confluent monolayers of WI-38 cells causes an increase (or the new appearance) of certain chromatin-bound protein kinases, and that this increase is inhibited by cyclic AMP in vivo.     

Blockage of prereplicative progression by cytochalasin D in serum-stimulated GC-7 cells

When growth-arrested GC-7 cells, a cell line from African green monkey kidney, are stimulated with 10% calf serum, they enter S phase 14-15 h later. Cytochalasin D at 0.6 micrograms/ml blocks the entrance into S phase, and inhibits, though only partially, the increase in protein synthesis after serum stimulation. Since partial inhibition of protein synthesis by cycloheximide interferes with accumulation of labile proteins and thus blocks the entrance of serum-stimulated cells into S phase, the effects of these two inhibitors are compared. Cytochalasin D at lower concentrations reduced the rate of entry into S phase without affecting the length of the prereplicative phase, whereas cycloheximide extended the prereplicative phase dose dependently without affecting the rate of entry into S phase. Cytochalasin D affected neither individual [35S]methionine-labeled spots on two-dimensional polyacrylamide-gel nor degradation of cellular proteins. These results indicate that cytochalasin D, though it interferes with protein synthesis, blocks prereplicative progression of serum-stimulated GC-7 cells in a different manner than cycloheximide.