Judith Campisi

Cell-cycle control of c-myc but not c-ras expression is lost following chemical transformation

Cellular oncogenes are DNA sequences implicated in the genesis of cancer, but their functions in the transformation process are not understood. Our experiments provide data linking expression of two well-studied proto-oncogenes, c-myc and c-rasKi, to current knowledge of proliferation control and its perturbation by differentiation and chemical transformation. Growth stimulation of quiescent cells by serum elevates expression of the myc proto-oncogene in Balb/c 3T3 (A31) cells. In two chemically transformed A31 derivatives (BPA31 and DA31), c-myc expression is constitutive. The levels of c-myc mRNA in quiescent and growing transformed cells are nearly the same, and are only slightly elevated compared to the level found in growing A31 cells. By contrast, c-rasKi expression is cell-cycle-dependent in BPA31 cells. The relative abundance of c-rasKi mRNA begins to increase in mid- to late G0/G1. During terminal differentiation of teratocarcinoma stem cells (F9) into nonproliferating endoderm, relative mRNA abundance is diminished more markedly for c-myc than for c-rasKi. These results demonstrate that expression of the myc and rasKi proto-oncogenes is dependent upon the cellular growth state, and that growth control exhibits growth-factor-dependent, cell-cycle-timed oncogene expression. In the case of the BPA31 cells, c-myc is not rearranged, amplified, or overexpressed. However, the oncogene has lost its cycle-dependent regulation in the chemically transformed cells.

c-myc regulation during retinoic acid-induced differentiation of F9 cells is posttranscriptional and associated with growth arrest.

We have shown that c-myc mRNA levels decrease more than 20-fold when F9 teratocarcinoma stem cells are induced to arrest growth and terminally differentiate to parietal endoderm after exposure to retinoic acid and cyclic AMP (Campisi et al., Cell 36:241-247, 1984). Here, we demonstrate that although growth arrest and full expression of the differentiated phenotype required about 3 days, c-myc mRNA declined abruptly between 8 and 16 h after the addition of retinoic acid and cyclic AMP. The decline was independent of cyclic AMP. We found little or no change in the level of c-myc transcription during differentiation, although two other genes showed marked transcriptional regulation. Thus, decreased c-myc mRNA is a consequence of very early posttranscriptional regulation directed by retinoic acid. Differentiation was not fundamental to this regulation. We have shown that sodium butyrate blocks expression of the differentiated phenotype if added within 8 h of retinoic acid and cyclic AMP (Levine et al., Dev. Biol. 105:443-450, 1984). However, butyrate did not inhibit the decrease in c-myc mRNA. Furthermore, F9 cells partially arrested growth without differentiating when grown in isoleucine-deficient medium. Under these conditions, c-myc mRNA levels also declined. Our results suggest that induction of differentiation-specific genes may be under retinoic acid-mediated control dissimilar from that responsible for the decay of c-myc mRNA. In addition, they raise the possibility that growth arrest may be initiated by reduced c-myc expression.

Post-transcriptional control of the onset of DNA synthesis by an insulin-like growth factor.

The control of eucaryotic cell proliferation is governed largely by a series of regulatory events which occur in the G1 phase of the cell cycle. When stimulated to proliferate, quiescent (G0) 3T3 fibroblasts require transcription, rapid translation, and three growth factors for the growth state transition. We examined exponentially growing 3T3 cells to relate the requirements for G1 transit to those necessary for the transition from the G0 to the S phase. Cycling cells in the G1 phase required transcription, rapid translation, and a single growth factor (insulin-like growth factor [IGF] I) to initiate DNA synthesis. IGF I acted post-transcriptionally at a late G1 step. All cells in the G1 phase entered the S phase on schedule if either insulin (hyperphysiological concentration) or IGF I (subnanomolar concentration) was provided as the sole growth factor. In medium lacking all growth factors, only cells within 2 to 3 h of the S phase were able to initiate DNA synthesis. Similarly, cells within 2 to 3 h of the S phase were less dependent on transcription and translation for entry into the S phase. Cells responded very differently to inhibited translation than to growth factor deprivation. Cells in the early and mid-G1 phases did not progress toward the S phase during transcriptional or translational inhibition, and during translational inhibition they actually regressed from the S phase. In the absence of growth factors, however, these cells continued progressing toward the S phase, but still required IGF at a terminal step before initiating DNA synthesis. We conclude that a suboptimal condition causes cells to either progress or regress in the cell cycle rather than freezing them at their initial position. By using synchronized cultures, we also show that in contrast to earlier events, this final, IGF-dependent step did not require new transcription. This result is in contrast to findings that other growth factors induce new transcription. We examined the requirements for G1 transit by using a chemically transformed 3T3 cell line (BPA31 cells) which has lost some but not all ability to regulate its growth. Early- and mid-G1-phase BPA31 cells required transcription and translation to initiate DNA synthesis, although they did not regress from the S phase during translational inhibition. However, these cells did not need IGF for entry into the S phase.

Kinetics of G1 transit following brief starvation for serum factors

Growing fibroblasts such as 3T3 cells are well-known to enter a quiescent state (G0) after many hours of serum deprivation. They emerge from G0 upon readdition of serum and initiate DNA synthesis about 12 h later. In this paper, we analyzed the effects of brief periods of serum deprivation on the ability of cells in G1 to initiate DNA synthesis. Exponentially growing 3T3 fibroblasts were briefly deprived of serum and their progress into S phase was monitored by autoradiography of labeled nuclei. When 10% serum was added back to cultures deprived of serum for a few hours, the progress of G1 cells into S phase was delayed for intervals far in excess of the length of the serum deprivation. Longer serum starvations resulted in longer excess delays. Several transformed 3T3 derivatives were markedly less sensitive to this serum-induced G1 regression following deprivation. When 1 microgram/ml insulin (rather than 10% serum) was added back to the starved cultures, the G1 cells entered S phase immediately. Delay in S phase entry following serum readdition was completely prevented if insulin (and, to a lesser extent, EGF) was present during the starvation, was diminished if a lower serum concentration was used for readdition, and was partially abolished if 10% serum plus insulin was restored to the cultures. The above results, then, suggest that serum deprivation sensitizes the cells to an unidentified serum component which sets the cells back in G1, unless insulin is present to maintain the flow of cells into S.

Butyrate inhibits the retinoic acid-induced differentiation of F9 teratocarcinoma stem cells

F9 mouse teratocarcinoma stem cells differentiate into parietal endoderm cells in the presence of retinoic acid, dibutyryl cyclic AMP, and theophylline (RACT). When F9 cells are exposed to 2-5 mM sodium butyrate plus RACT, they fail to differentiate. Differentiation is assessed by induction of laminin and collagen IV mRNA, the synthesis of laminin, collagen IV and plasminogen activator proteins, and alterations in cell morphology. Butyrate inhibits differentiation only when added within 8 hr after retinoic acid addition. Thus an early event in retinoid action on F9 cells is butyrate-sensitive. The population doubling time and cell cycle distribution of F9 cells are not altered within the first 24 hr after butyrate addition, suggesting that butyrate does not inhibit differentiation by inhibition of growth or normal cycling. However, butyrate does inhibit histone deacetylation in F9 cells, and this could be the mechanism by which butyrate inhibits differentiation.

An artifact in measurement of S phase initiation and its implication for the kinetics of S phase-specific enzyme activities☆

Abstract It is shown that the different onset of S phase as measured by autoradiography vs cumulative thymidine uptake is an artifact. We consequently propose that S phase-specific enzyme activities may accumulate a few hours prior to the actual initiation of DNA synthesis. A “pre-S” DNA synthesis that can be readily detected only by autoradiography has been proposed. Published data show that DNA synthesis in cultured animal cells is initiated approx. 2 h later when measured by cumulative incorporation of [ 3 H ]thymidine ([ 3 H ]TdR) as compared with autoradiography. We show here that the difference is in reality an artifact, owing to not taking into account both gradual, asynchronous entry of cells into S phase, as well as time-dependent accumulation of radioactivity into each cell after it has entered S phase. Combination of these two factors leads to the conclusion that [ 3 H ]TdR should be incorporated approximately as the square of time following entry of the first cell into S. Taking this into account, the two methods then are in agreement, as predicted. This argument also applies to the enzyme activities shown to increase with DNA synthesis in synchronized cultures. Such an enzyme accumulation really could begin some time earlier than indicated by conventional plots of cumulative enzyme activity vs time and may, in fact, precede the onset of S by a few hours.

The study of DNA-repair defects using [125I]iododeoxycytidine incorporation as an assay for the growth of herpes simplex virus

[125I]Iododeoxycytidine incorporation was used to measure herpes virus (HSV-1) DNA synthesis following specific DNA damage. Xeroderma pigmentosum fibroblasts were less able to replicate UV-irradiated viral DNA than were normal fibroblasts, indicating the necessity for excision repair for the survival of UV-irradiated virus. Because of its rapidity and ease of quantitation, this assay had advantages over standard viral mediated assays of DNA excision repair. It was possible to monitor viral replication as a function of the cellular cell cycle. Other genetic defects which have been proposed to reflect deficiencies in DNA-repair capacity were not detected by this assay. DNA-repair inhibitors, caffeine and 3-aminobenzamide, also did not show synergistic lethal effects on the replication of damaged viral DNA.