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.     

Time of c-fos and c-myc expression in human diploid fibroblasts stimulated to proliferate after prolonged periods in quiescence

When human diploid fibroblasts such as WI-38 cells become crowded, they enter a viable state of quiescence (G0) in which they can remain for prolonged periods of time. These quiescent cells can be induced to re-enter the cell cycle by addition of fresh serum. However, cells held in G0 for long periods before stimulation require more time to enter DNA synthesis as compared to cells held in a quiescent state for short periods. We have used this model system to determine if a close temporal coupling exists between the time of expression of two proto-oncogenes associated with cell growth, c-fos and c-myc, and the time of entry into DNA synthesis. WI-38 cells were stimulated to enter DNA synthesis by the addition of fresh culture medium and serum at various lengths of time after plating, ranging from 7 to 34 days. At hourly intervals thereafter, cells were harvested and total RNA was isolated. These samples were then analyzed by RNase protection assay to determine the levels of c-fos and c-myc mRNA. Our results show that the time and pattern of c-fos and c-myc mRNA accumulation after stimulation is determined only by the time which the cells are treated with serum even when they exhibit a 19-h delay in the entry into DNA synthesis. In all of our experiments, c-fos could be detected 0.5 h after stimulation and remained detectable for approximately 2 h. Likewise, the peak of c-myc accumulation occurred at about 3 h after serum addition, regardless of how long it took to initiate DNA synthesis. These results suggest that the time of c-fos and c-myc induction clearly is not the only factor which determines the length of the prereplicative period and thus the ultimate time of initiation of DNA synthesis.     

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.     

Synthesis of nuclear acidic proteins in density-inhibited fibroblasts stimulated to proliferate

Previous work from this laboratory (Rovera and Baserga, 1971) has shown that, when density-inhibited WI-38 human diploid fibroblasts are stimulated to proliferate by a change of medium, the synthesis of nuclear acidic proteins increases within 30 minutes after stimulation; several hours before DNA synthesis begins to increase. Similar results have now been obtained with density-inhibited 3T6 mouse fibroblasts, also stimulated by a change of medium. Gel electrophoretic analysis of nuclear acidic proteins in both WI-38 human diploid fibroblasts and 3T6 mouse fibroblasts stimulated to proliferate indicates that the increased synthesis of nuclear acidic proteins is limited to certain classes of proteins while other classes are totally unaffected. The increase in nuclear acidic proteins synthesis is inhibited when WI-38 cells or 3T6 cells are stimulated in the presence of 5-azacytidine (10 μg/ml), a treatment which also inhibits the subsequent stimulation of DNA synthesis. These results, confirming and extending similar findings previously reported in other models of stimulated DNA synthesis, lend further support to the hypothesis that nuclear acidic proteins may play a critical role in the control of DNA synthesis and cell division in mammalian cells.     

Effect of cell cycle inhibitor p19ARF on senescence of human diploid cell

To investigate the effect of cell cycle inhibitor p19ARF on replicative senescence of human diploid cell,recombinant p19ARF eukaryotic expression vector was constructed and p19ARF gene was transfected into human diploid fibroblasts (WI-38 cells) by liposome-mediated transfection for overexpression.Then, the effects of p19ARF on replicative senescence of WI-38 cells were observed. The results revealed that, compared with control cells, the WI-38 cells in which p19ARFgene was introduced showed significant up-regulation of p53 and p21 expression level, decrease of cell generation by 10-12 generations, decline of cell growth rate with cell cycle being arrested at G1 phase, increase of positive rate of senescent marker SA-β-gal staining, and decrease of mitochondrial membrane potential. The morphology of the transfected fibroblasts presented the characteristics changes similar to senescent cells.These results indicated that high expression of p19ARF may promote the senescent process of human diploid cells.     

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.     

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.     

WI-38 cell long-term quiescence model system: A valuable tool to study molecular events that regulate growth

A number of cell culture model systems have been used to study the regulation of cell cycle progression at the molecular level. In this paper we describe the WI-38 cell long-term quiescence model system. 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. Through studies aimed at understanding the cause and molecular nature of the prolongation of the prereplicative phase, we have determined that gene expression plays an important role in establishing growth factor “competence” and that once the cell becomes “competent” there is a defined order to the molecular events that follow during the remainder of G-1. More specifically, we have determined that the prolongation represents a delay in the ability of long term quiescent cells to become fully “competent” to respond to growth factors which regulate progression through G-1 into S. This prolongation appears to occur as a result of changes during long term quiescence in the ability of immediate early G-1 specific genes (such as c-myc) to activate the expression of early G-1 specific genes (such as ornithine decarboxylase). While ODC is the first and thus far only growth associated gene identified as a target of c-myc (and the Myc/Max protein complex), it is likely that further studies in this model system will reveal other early G-1 growth regulatory genes. We anticipate that future follow-up studies in this model system will provide additional valuable information abuot the function of growth-regulatory genes in controlling growth factor responsiveness and cell cycle progression.     

Platelet factors stimulate fibroblasts and smooth muscle cells quiescent in plasma serum to proliferate

Whole blood serum is widely recognized as essential for the growth of diploid cells in culture. Dermal fibroblasts and arterial smooth muscle cells fail to proliferate in culture in the presence of serum derived from platelet-poor plasma. Platelet-poor plasma serum is capable of maintaining monkey arterial smooth muscle cells quiescent in culture at either low (1.5 x 10(3)) or high (2.0 x 10(4)) population densities. The proportion of cell traversing the cell cycle under these conditions was approximately 3%. Equal numbers of quiescent smooth muscle cells initiated DNA synthesis and cell division when treated with whole blood serum or with an equivalent quantity of platelet-poor plasma serum supplemented with a factor(s) derived from a supernate obtained after exposure of human platelets to purified thrombin in vitro.     

Cell cycle dependent growth factor regulation of gene expression

The expression of the proto-oncogenes c-fos and c-myc is a rapid response of G0-arrested fibroblasts to serum and peptide growth factors; however, the role of the c-fos and c-myc gene products in subsequent cell cycle transit is not understood. We examined the expression of c-fos and c-myc mRNA in Balb/c 3T3 murine fibroblasts in response to platelet-derived growth factor (PDGF) and platelet-poor plasma, using arrest points associated with density dependent growth inhibition or metabolic inhibition to synchronize cells in S phase of the cell cycle. The expression of c-fos and c-myc mRNA in Balb/c 3T3 cells was differentially regulated with respect to growth factor dependence and cell cycle dependence. c-fos expression was induced in the presence of PDGF and was unaffected by plasma. The induction of c-fos expression in response to PDGF was cell cycle independent, occurring in cells transiting S phase and G2 as well as in G0 arrest. In contrast, c-myc expression was both growth factor and cell cycle dependent. In G0 arrested cells, c-myc expression was PDGF-dependent and plasma-independent, and PDGF was required for maintenance of elevated c-myc levels during G1 transit. In cells transiting S phase, c-myc mRNA was induced in response to PDGF, but was also plasma-dependent in S phase cells that had been "primed" by exposure to PDGF during S phase.     

gamma-Glutamyltransferase in human diploid fibroblasts and other mammalian cells.

gamma-Glutamyltransferase was determined in WI-38 human diploid fibroblasts and compared to enzyme levels determined in several other mammalian cell lines including: fibroblast-like cells from human skin, tibia and foreskin; epithelial-like cells from human, bovine and monkey kidney; and transformed cells (Chinese hamster ovary, HeLa S3 and SV-40 transformed WI-38). Transformed cells had the lowest activity found followed in increasing order by fibroblasts, human and bovine epithelial cells and monkey kidney epithelial cells. The enzyme isolated from the plasma membrane of WI-38 cells, like the enzyme from kidney and brain, was found to be irreversibly inhibited by iodoacetamide, reversibly by serine-borate, and had a strong specificity for certain amino acids. The possibility exists that gamma-glutamyltransferase could be involved in transport of amino acids into cells in culture; and glutamine, used in media, is an excellent substrate for the enzyme.     

Regulation of human ornithine decarboxylase expression following prolonged quiescence: Role for the c-Myc/Max protein complex

WI-38 cells can remain quiescent for long periods of time and still be induced to reenter the cell cycle by the addition of fresh serum. However, the longer these cells remain growth arrested, the more time they require to enter S phase. This prolongation of the prereplicative phase has been localized to a point early in G₁, after the induction of “immediate early” G₁ genes such as c-fos and c-jun but before maximal expression of “early” G₁ genes such as ornithine decarboxylase (ODC). Understanding the molecular basis for ODC mRNA induction can therefore provide information about the molecular events which regulate the progression of cells out of long-term quiescence into G₁ and subsequently into DNA synthesis. Studies utilizing electrophoretic mobility shift assays (EMSA) of nuclear extracts from short- and long-term quiescent WI-38 cells identified a region of the human ODC promoter at ?491 bp to ?474 bp which exhibited a protein binding pattern that correlated with the temporal pattern of ODC mRNA expression. The presence of a CACGTG element within this fragment, studies with antibodies against c-Myc and Max, the use of purified recombinant c-Myc protein in the mobility shift assay, and antisense studies suggest that these proteins can specifically bind this portion of the human ODC promoter in a manner consistent with growth-associated modulation of the expression of ODC and other early G₁ genes following prolonged quiescence. These studies suggest a role for the c-Myc/Max protein complex in regulating events involved in the progression of cells out of long-term quiescence into G₁ and subsequently into S. © 1995 Wiley-Liss, Inc.     

Expression of growth-regulated genes in tsJT60 cells, a temperature-sensitive mutant of the cell cycle

We have investigated the expression of growth-regulated genes in tsJT60 cells, a temperature-sensitive (ts) mutant of Fischer rat cells, which, on the basis of its kinetic behavior, can be classified as a G0 mutant. It grows normally at 34 degrees C and also at 39.5 degrees C if shifted to the higher temperature during exponential growth. However, if the cell population is first made quiescent by serum deprivation, subsequent stimulation by serum induces the cells to enter S phase at 34 degrees C but not at 39.5 degrees C. A panel of growth-regulated genes was used that included three protooncogenes (c-fos, c-myc, and p53), several genes that are induced in G0 cells stimulated by growth factors (beta-actin, 2A9, 2F1, vimentin, JE-3, KC-1, and ornithine decarboxylase), and an S-phase gene (histone H3). The expression of these growth-regulated genes was studied in both tsJT60 cells and its parental cell line, rat 3Y1 cells. All the genes tested, except histone H3, are similarly induced when quiescent tsJT60 cells are stimulated by serum at either permissive or restrictive temperatures. These results raise intriguing questions on the nature of quiescence and the relationship between G0 and G1 in cells in culture.     

Effect of cell cycle inhibitor p19ARF on senescence of human diploid cell

To investigate the effect of cell cycle inhibitor p19ARF on replicative senescence of human diploid cell, recombinant p19ARF eukaryotic expression vector was constructed and p19ARF gene was transfected into human diploid fibroblasts (WI-38 cells) by liposome-mediated transfection for overexpression. Then, the effects of p19ARF on replicative senescence of WI-38 cells were observed. The results re- vealed that, compared with control cells, the WI-38 cells in which p19ARF gene was introduced showed significant up-regulation of p53 and p21 expression level, decrease of cell generation by 10 12 generations, decline of cell growth rate with cell cycle being arrested at G1 phase, increase of positive rate of senescent marker SA-β-gal staining, and decrease of mitochondrial membrane potential. The morphology of the transfected fibroblasts presented the characteristics changes similar to senescent cells. These results indicated that high expression of p19ARF may promote the senescent process of human diploid cells.     

Screening of senescence-associated genes with specific DNA array reveals the role of IGFBP-3 in premature senescence of human diploid fibroblasts

Repeated exposures to sublethal concentrations of tert-butylhydroperoxide and ethanol trigger premature senescence of WI-38 human diploid fibroblasts. We found 16 replicative senescence-related genes with similar alterations in expression level in replicative senescence and two models of stress-induced premature senescence. Among these genes was IGFBP-3. Using a siRNA approach, we showed that IGFBP-3 regulates the appearance of several biomarkers of senescence after repeated exposures of WI-38 fibroblasts to tert-butylhydroperoxide and ethanol.     

Growth kinetics rather than stress accelerate telomere shortening in cultures of human diploid fibroblasts in oxidative stress-induced premature senescence

WI-38 human diploid fibroblasts underwent accelerated telomere shortening (490 bp/stress) and growth arrest after exposure to four subcytotoxic 100 microM tert-butylhydroperoxide (t-BHP) stresses, with a stress at every two population doublings (PD). After subcytotoxic 160 microM H2O2 stress or five repeated 30 microM t-BHP stresses along the same PD, respectively a 322 +/- 55 and 380 +/- 129 bp telomere shortening was observed only during the first PD after stress. The percentage of cells resuming proliferation after stress suggests this telomere shortening is due to the number of cell divisions accomplished to reach confluence during the first PD after stress.     

Selective Loss of CDC2 and CDK2 Induction by Tumor Necrosis Factor-α in Senescent Human Diploid Fibroblasts

Normal human diploid fibroblasts undergo a finite number of doublings in culture. This process of senescence is accompanied by a loss in the ability to respond to proliferative stimuli and is therefore distinct from the quiescent state induced by nutrient deprivation. We have studied changes in gene expression induced in these cells following exposure to the cytokine, tumor necrosis factor-α (TNF). We observed that TNF induced CDC2 and CDK2 expression in early-passage quiescent WI-38 fibroblasts. However, as cells approached senescence, their ability to induce CDC2 and CDK2, as well as stimulate DNA synthesis in response to TNF, progressively declined, with minimal to absent induction in senescent cells. This occurred despite the TNF-dependent induction of such proliferation-independent genes as manganese superoxide dismutase and interleukin-6 in senescent and quiescent cells. Serum was similarly unable to induce CDC2 or CDK2 expression in senescent cells. These results demonstrate that senescent cells are selectively deficient in TNF-mediated induction of CDC2 and CDK2, genes crucial to DNA synthesis and mitosis.     

DNA damage caused by ionizing radiation in embryonic diploid fibroblasts WI-38 induces both apoptosis and senescence

Cellular response to ionizing radiation-induced damage depends on the cell type and the ability to repair DNA damage. Some types of cells undergo apoptosis, whereas others induce a permanent cell cycle arrest and do not proliferate. Our study demonstrates two types of response of embryonic diploid fibroblasts WI-38 to ionizing radiation. In the WI-38 cells p53 is activated, protein p21 increases, but the cells are arrested in G2 phase of cell cycle. Some of the cells die by apoptosis, but in remaining viable cells p16 increases, senescence associated DNA-damage foci occur, and senescence-associated beta-galactosidase activity increases, which indicate stress-induced premature senescence.     

Cell population heterogeneity in the inducibility of DNA synthesis in human diploid fibroblasts

The initiation of nuclear DNA synthesis has been studied in cytochalasin B (CB)-induced binucleate human diploid fibroblasts (WI-38 cells). Mitotic cells from different passage levels were rendered binucleate by a brief pulse of CB. The cells were then washed free of the drug, and DNA synthesis was studied by [3H]thymidine labeling. The results showed that, in a small percentage of binucleate cells, one nucleus was labeled (S phase) and the other nucleus was unlabeled (G1 phase). There was no significant difference in the percentage of these cells with increasing passage levels. The results of this study suggest that some WI-38 cells retire from the cell cycle at different passage levels, and thereby become refractory to inducers of nuclear DNA synthesis generated by sister cells in S phase.     

Cell cycle regulation of DNA repair in normal and repair deficient human cells

The regulation of nucleotide excision repair and base excision repair by normal and repair deficient human cells was determined. Synchronous cultures of WI-38 normal diploid fibroblasts and Xeroderma pigmentosum fibroblasts (complementation group D) (XP-D) were used to investigate whether DNA repair pathways were modulated during the cell cycle. Two criteria were used: (1) unscheduled DNA synthesis (UDS) in the presence of hydroxyurea (HU) after exposure to UV light or after exposure to N-acetoxy-acetylaminofluorene (N-AcO-AAF) to quantitate nucleotide excision repair or UDS after exposure to methylmethane sulfonate (MMS) to measure base excision repair; (2) repair replication into parental DNA in the absence of HU after exposure to UV light. Nucleotide excision repair after UV irradiation was induced in WI-38 fibroblasts during the cell cycle reaching a maximum in cultures exposed 14–15 h after cell stimulation. Similar results were observed after exposure to N-AcO-AAF. DNA repair was increased 2–4-fold after UV exposure and was increased 3-fold after N-AcO-AAF exposure. In either instance nucleotide excision repair was sequentially stimulated prior to the enhancement of base excision repair which was stimulated prior to the induction of DNA replication. In contrast XP-D failed to induce nucleotide excision repair after UV irradiation at any interval in the cell cycle. However, base excision repair and DNA replication were stimulated comparable to that enhancement observed in WI-38 cells. The distinctive induction of nucleotide excision repair and base excision repair prior to the onset of DNA replication suggests that separate DNA repair complexes may be formed during the eucaryotic cell cycle.