Repression of quiescence-specific polypeptides in chicken heart mesenchymal cells transformed by Rous sarcoma virus.

Chicken heart mesenchymal cells do not proliferate in medium of physiological composition containing plasma (S. Balk, Proc. Natl. Acad. Sci. USA 77:6606-6610, 1980). To understand the molecular events involved in cell quiescence and in the initiation of cell division under physiological conditions, we examined the differences in the patterns of protein synthesis of quiescent, hormone-stimulated, and Rous sarcoma virus-transformed chicken heart mesenchymal cells. We describe the expression of a 20,000-kilodalton (kDa) polypeptide actively synthesized by quiescent cells but not by their transformed counterparts. Normal chicken heart mesenchymal cells stimulated with epidermal growth factor and insulin also repressed the synthesis of the 20,000-kDa polypeptide while actively growing but synthesized increasing amounts of the protein at high cell density (confluence). The synthesis of the 20,000-kDa protein is not restricted to chicken heart mesenchymal cells, since confluent, density-arrested chicken embryo fibroblasts also expressed high levels of the protein. Transformed chicken heart mesenchymal cells and embryo fibroblasts did not synthesize the protein even at high cell density. The 20,000-kDa polypeptide accumulated in the culture medium.

Heparin-treated, v-myc-transformed chicken heart mesenchymal cells assume a normal morphology but are hypersensitive to epidermal growth factor (EGF) and brain fibroblast growth factor (bFGF); cells transformed by the v-Ha-ras oncogene are refractory to EGF and bFGF but are hypersensitive to insulin-like growth factors.

Chicken heart mesenchymal cells do not proliferate in culture medium containing heat-defibrinogenated plasma but proliferate briskly when incubated with epidermal growth factor (EGF) or brain fibroblast growth factor (bFGF) plus insulin-like growth factors (IGFs) or when infected with sarcoma or erythroblastosis viruses. When infected with the retrovirus MC29, which bears a v-myc oncogene, chicken heart mesenchymal cells proliferate at a more modest rate and become morphologically transformed. Heparin at 25 microgram/ml causes these MC29-transformed cells to become proliferatively quiescent and to assume a normal morphology. Heparin-treated MC29-infected cells are, however, 100 times more sensitive to EGF than are their normal, uninfected counterparts. MC29-infected cells appear, likewise, to be hypersensitive to bFGF and to PDGF preparations but not to insulin. We hypothesize, therefore, (i) that heparin prevents the generation by cells of a mitogen from plasma protein precursors in the culture medium; (ii) that the v-myc oncogene renders cells hypersensitive to EGF, bFGF, PDGF, and the putative plasma-protein-derived mitogen; and (iii) that MC29-infected cells must proliferate in order to manifest the transformed morphology. Chicken heart mesenchymal cells infected with a recombinant spleen necrosis virus containing a v-ras oncogene are morphologically transformed but proliferate only sluggishly in plasma-containing medium without added mitogenic hormones. Heparin does not significantly affect their behavior. They are refractory to mitogenic stimulation by EGF or bFGF suggesting that ras proteins mediate the effects of receptors for these hormones. The SNV/v-ras-infected cells proliferate briskly, however, in response to hyperphysiological concentrations of insulin, an IGF surrogate, and are considerably more sensitive to this IGF mitogenicity than are their normal, uninfected counterparts.

Phorbol 12-myristate 13-acetate, ionomycin or ouabain, and raised extracellular magnesium induce proliferation of chicken heart mesenchymal cells.

Cultured chicken heart mesenchymal cells are proliferatively quiescent at low densities in medium containing plasma at 10%. Mitogenic hormones like epidermal growth factor and insulin-like growth factors cause these cells to proliferate very actively, as does infection with avian sarcoma viruses, erythroblastosis virus, or myelocytomatosis virus. We have found that the combination of phorbol 12-myristate 13-acetate (PMA), ionomycin or ouabain, and raised extracellular magnesium, likewise, causes these cells to proliferate very actively. Although these agents have no significant effect when acting singly, the combination of PMA at 100 ng/ml and 0.5 microM ionomycin induces a 6-fold increase in cell number at 4 days, and the combination of PMA, ionomycin, and 5.6 mM magnesium induces 12-fold multiplication. Likewise, PMA plus 1 microM ouabain induces 3-fold multiplication, whereas the combination of PMA, ouabain, and magnesium induces 6-fold multiplication. The tumor promoter PMA, like diacylglycerol released by breakdown of plasma membrane phosphatidylinositol diphosphate, is known to activate the serine- and threonine-specific intracellular enzyme kinase C. The divalent cation ionophore ionomycin is known to carry calcium into cells down an electrochemical gradient, and the Na+,K+-ATPase inhibitor ouabain appears to elevate intracellular calcium by means of a sodium-mediated exchange mechanism. Magnesium, like calcium, is known to enter cells passively down an electrochemical gradient and to be involved in the regulation of many key intracellular reactions. Our findings with PMA, ionotropes, and magnesium support a hypothesis that diacylglycerol-mediated activation of kinase C plus cellular divalent cation influx and/or mobilization, caused by the action of mitogenic hormones or the protein products of onc genes, are key events in the initiation of cell replication.

Morphological transformation, autonomous proliferation and colony formation by chicken heart mesenchymal cells infected with avian sarcoma, erythroblastosis and myelocytomatosis viruses.

Normal chicken heart mesenchymal cells at low density in monolayer culture in plasma-containing medium have a polygonal shape and are proliferatively quiescent. The combination of epidermal growth factor and insulin at hyperphysiological concentration, an insulin-like growth factor surrogate, causes these cells to assume a fusiform shape and to increase 40-fold in number during four days of incubation. These mitogenic hormones do not, however, induce normal chicken heart mesenchymal cells to form colonies in agarose suspension culture. Chicken heart mesenchymal cells infected with the Schmidt-Ruppin or Prague-A strains of Rous sarcoma virus or with the Fujinami or Y73 avian sarcoma viruses assume spindle and round shapes, increase 50-100 fold in number during four days of monolayer culture in the absence of mitogenic hormones and form macroscopic colonies during 3-4 days of agarose suspension culture. The autonomous (mitogenic hormone-independent) proliferation, in monolayer culture, of cells infected with temperature-sensitive transformation mutants of Rous sarcoma virus (tsNY68, tsNY72, tsLA24, tsLA29) is temperature-sensitive. Chicken heart mesenchymal cells infected with avian erythroblastosis virus assume spindle shapes and proliferate in monolayer culture at a rate comparable to that of sarcoma virus-infected cells but do not, however, form colonies in agarose suspension culture. Cells infected with the myelocytomatosis virus MC29 assume stellate shapes and increase 18-fold in number during four days of monolayer culture. Cells infected with the myelocytomatosis virus MH2 assume fusiform shapes and increase fourfold in number during four days of monolayer culture. Neither MC29 nor MH2 renders chicken heart mesenchymal cells capable of colony formation in agarose suspension culture. Infection with avian leukosis viruses (RAV-1, RAV-2, RPL-42) or with transformation-defective mutants of Rous sarcoma virus (tdNY105, 107, 109) does not affect the morphology or proliferative behavior of chicken heart mesenchymal cells. Monolayer culture of chicken heart mesenchymal cells in plasma-containing medium appears, therefore, to define the ability of onc genes of acute transforming avian retroviruses to induce autonomous (mitogenic hormone-independent) cell proliferation, the essential characteristic of neoplasia. The differences in transformed morphology and rates of autonomous proliferation between cells infected with different acute transforming retroviruses probably reflects differences in the modes of action of the transforming proteins encoded by the onc genes of the respective viruses.(ABSTRACT TRUNCATED AT 400 WORDS)

Somatomedins (insulin-like growth factors), but not growth hormone, are mitogenic for chicken heart mesenchymal cells and act synergistically with epidermal growth factor and brain fibroblast growth factor.

Chicken, ovine or human growth hormones have no mitogenic effect on chicken heart mesenchymal cells, which are proliferatively quiescent at low culture densities in medium containing heparinized, heat-defibrinogenated rooster plasma at 10%. Sm-C/IGF-I (15 ng/ml; 2 nM), MSA/rIGF-II (50 ng/ml; 7 nM), insulin (10,000 ng/ml; 1750 nM) or proinsulin (16,000 ng/ml; 1750 nM), however, cause these cells to increase threefold in number during four days of incubation. While EGF alone at 100 ng/ml causes threefold multiplication at four days and brain FGF causes a sixfold increase, EGF acts synergistically with Sm-C/IGF-I, MSA/rIGF-II, insulin or proinsulin to cause 18-fold multiplication, and brain FGF acts synergistically with IGFs to cause 20-fold multiplication. EGF and brain FGF, however, show no mitogenic synergy. Addition to the plasma-containing culture medium of a monoclonal antibody to Sm-C/IGF-I nearly abolishes the mitogenic effect of added EGF or brain FGF but does not affect the autonomous (mitogenic hormone-independent) proliferation of RSV-infected chicken heart mesenchymal cells. These findings support the somatomedin hypothesis for growth hormone action and suggest that potentiation of the activity of other mitogenic hormones, like EGF and FGF, makes a significant contribution to control of cell proliferation by the GH/IGF axis.

Effect of reduction of culture medium sodium, using different sodium chloride substitutes, on the proliferation of normal and Rous sarcoma virus-infected chicken fibroblasts.

We have substituted choline chloride, tetramethylammonium chloride, sucrose, or glucose for culture medium sodium chloride. When culture medium sodium is reduced below physiological levels (143 mM) by replacement of graded concentrations of sodium chloride with equivalent concentrations of choline chloride, normal fibroblasts approach proliferative inactivity in the presence of 90 mM Na, while their Rous sarcoma virus (RSV)-infected counterparts proliferate actively; both normal and neoplastic cells die with further sodium reduction. When culture medium NaC; is replaced with tetramethylammonium chloride, however, both normal and RSV-infected fibroblasts alike approach proliferative inactivity in the presence of 110 mM Na and both die off in the presence of 90 mM Na. When culture medium NaCl is replaced with sucrose or glucose yet another set of results is obtained: both normal and RSV-infected fibroblasts proliferate at reduced, although significant, rates in the presence of 42 mM Na. It is clear from our experimental results that the effects of reduction of culture medium sodium on cell proliferation differ markedly with the use of different sodium chloride substitutes. Caution must be exercised, therefore, in drawing inferences concerning the role of sodium in mitogenesis from experimental studies based on the tactic of reduction of external sodium.

Epidermal growth factor and insulin cause normal chicken heart mesenchymal cells to proliferate like their Rous sarcoma virus-infected counterparts.

Normal chicken heart mesenchymal cells at low culture density are proliferatively quiescent in a physiological culture medium containing heparinized, heat-inactivated, chicken plasma at 10%. Rous sarcoma virus-infected chicken heart mesenchymal cells, on the other hand, proliferate maximally in this same medium, undergoing a 60-fold increase in cell number during 4 days of exponential growth. When normal heart mesenchymal cells are cultured for 4 days in the presence of epidermal growth factor at 1 micrograms/ml they undergo a 16-fold increase in number, with graded responses to lower concentrations of the factor. In the presence of insulin at 10 micrograms/ml, normal heart mesenchymal cells multiply by a factor of 3 over a 4-day period. The addition of epidermal growth factor (1 microgram/ml) and insulin (10 micrograms/ml) to cultures of normal chicken heart mesenchymal cells causes these cells to proliferate at a rate comparable to that of their RSV-infected counterparts.

Mitogenic factors present in serum but not in plasma.

In culture medium containing heparinized, heat-inactivated, chicken plasma, normal chicken heart mesenchymal cells do not proliferate but their Rous sarcoma virus-infected counterparts proliferate maximally. In medium containing serum derived from chicken whole blood or plasma, on the other hand, normal chicken heart mesenchymal cells proliferate actively, at similar overall rates and to similar extents. The rate and extent of normal cell proliferation are decreased by a factor of approximately 1/2 with whole blood-derived serum that is heparinized and inactivated; proliferation ceases in plasma-derived serum that is heparinized and inactivated. Heparinization and inactivation of serum does not affect the proliferation of Rous sarcoma virus-infected cells, indicating that this combined treatment eliminates a mitogenic (regulatory) rather than a supportive (nutrient) factor(s) for cell replication. We hypothesize that mitogen(s) is released from plasma protein precursors when plasma clots in the presence of formed elements of the blood or when plasma-derived serum is exposed to cultured cells; heparinization and inactivation, within the framework of this hypothesis, would render nonfunctional the plasma protein precursor(s) from which the mitogen(s) is generated. Alternatively, our data are consistent with the release of two mitogens during blood clotting, one from plasma protein precursors and the other from formed elements of the blood. We also have studied the proliferative behavior of Swiss and BALB/c 3T3 cells in whole blood-derived and plasma-derived human serum. Our studies suggest that the platelet-derived growth factor has an artifactual supportive (nutrient) role, rather than an authentic mitogenic role, in cell replication.

Active proliferation of Rous sarcoma virus-infected, but not normal, chicken heart mesenchymal cells in culture medium of physiological composition.

Normal as well as Rous sarcoma virus-infected chicken pectoral and chicken embryo fibroblasts proliferate actively in a plasma containing medium of physiological ion concentrations (Ca2+, 1.2 mM; Mg2+, 0.7 mM). Reduction of medium calcium and magnesium concentrations is necessary to achieve selective quiescence of normal fibroblasts in these cell systems. By contrast, normal chicken heart mesenchymal cells proliferate only sluggishly (one doubling or less during a 6-day period) in a plasma containing medium of physiologic ion concentrations, whereas Rous sarcoma virus-infected heart mesenchymal cells proliferate actively (more than four doublings during an initial 2-day phase of exponential growth). The chicken heart mesenchymal cell system therefore has great potential for studies of the mechanism that initiates cell replication and of the failure in cellular regulatory processes that is responsible for the autonomous initiation of replication of neoplastic cells. From comparison of the chicken heart mesenchymal cell system to dialyzed plasma-based systems in which 3T3 cells tend to proliferative quiescence, it is argued that this proliferative quiescence of 3T3 cells is a result of cell starvation and is not physiologically meaningful.

Proliferation of Rous sarcoma virus-infected, but not of normal, chicken fibroblasts in a medium of reduced calcium and magnesium concentration.

Both normal and Rous sarcoma virus-infected chicken fibroblasts proliferate actively in a culture medium containing physiological concentrations of calcium (1.2 mM) and magnesium (0.7 mM). In the presence of a physiological concentration of magnesium, reduction of the calcium concentration to 0.125 mM resulted in a significant decrease in the proliferation of the normal, but not of the neoplastic, fibroblasts. Reduction of the magnesium concentration to 0.05 mM in the presence of a physiological concentration of calcium had a similar effect. In a culture medium containing reduced concentrations of both calcium (0.20 mM) and magnesium (0.05 mM), the normal fibroblasts were maintained without proliferation, whereas the Rous sarcoma virus-infected fibroblasts continued to proliferate actively. The cytosol concentrations of ionized calcium and magnesium are known to be regulated by a balance between net passive influx and active extrusion and sequestration. On the basis of this consideration and the findings described above it can be hypothesized that: (i) Fibroblast replication is initiated when cytosolic concentrations of calcium, magnesium, or both rise above a critical level. (ii) Autonomous initiation of replication of neoplastic fibroblasts is a result of failure of cytoplasmic divalent cation homeostasis; alternatively, sarcoma virus infection may endow cells with a divalent cation-independent mechanism that bypasses an initiation mechanism that is, normally, divalent cation-dependent. (iii) Proliferation of normal fibroblasts is controlled by extracellular matrix components that interact with cell surfaces in a manner that limits the permeability of plasma membranes to divalent cations or otherwise functions to lower cytosol divalent cation concentrations.

Thymidine and hypoxanthine requirements for the proliferation of normal and Rous sarcoma virus-infected chicken fibroblasts in the presence of methotrexate.

Cultured normal and Rous sarcoma virus-infected chicken fibroblasts do not differ in the concentrations of thymidine or of hypoxanthine that they require to proliferate in the presence of a methotrexate block. For maximal proliferation, thymidine is required at 10(-6) M, while hypoxanthine is required at 10(-5) M. The normal and Rous-infected fibroblasts show very similar, if not identical, decreases in proliferation rates at suboptimal concentrations of thymidine or hypoxanthine. These results suggest that conversion of fibroblasts to the neoplastic state does not alter their capacity to salvage thymidine or purines from the extracellular fluid or to metabolize these compounds.

5-Methyltetrahydrofolic acid, 5-formyltetrahydrofolic acid (folinic acid), and folic acid requirements of normal and Rous sarcoma virus-infected chicken fibroblasts.

Normal and Rous sarcoma virus-infected chicken fibroblasts proliferate maximally in a culture medium containing a physiological (10 ng/ml) concentration of 5-methyltetrahydrofolic acid or folinic acid (5-formyltetrahydrofolic acid), while their maximal proliferation requires a hyperphysiological (1000 ng/ml) concentration of folic acid. The normal and Rous-infected fibroblasts do not differ in their requirements for 5-methyltetrahydrofolate, folinic acid, or folic acid.

Proliferation of Rous sarcoma virus-infected, but not of normal, chicken fibroblasts in oxygen-enriched environment: preliminary report.

Both normal and Rous sarcoma virus-infected chicken fibroblasts proliferate in an incubator containing 95% air, 5% CO2. In an incubator atmosphere enriched with oxygen, however, the normal fibroblasts are maintained without proliferation, while the Rous sarcoma virus-infected fibroblasts continue to proliferate. This suggests that a respiratory function may be involved in the regulation of proliferation of normal cells, and that neoplastic cells may proliferate autonomously because of a deficiency in this regulatory function.

The failure of methotrexate to inhibit chicken fibroblast proliferation in a serum-containing culture medium.

Methotrexate (1 muM) abolishes the proliferation of chicken fibroblasts in a culture medium containing defibrinogenated chicken plasma but does not affect proliferation in a medium containing chicken serum.

Roles of calcium, serum, plasma, and folic acid in the control of proliferation of normal and Rous sarcoma virus-infected chicken fibroblasts.

In a culture medium of pH 7.4 and a folic acid concentration of 100 mug/liter that contains 5% heat-inactivated chicken plasma rather than serum, the rate of proliferation of normal chicken fibroblasts is determined by the concentration of calcium. Proliferation, rapid when the calcium concentration is physiological, decreases when the calcium concentration is reduced. At a very low calcium concentration, in this culture medium, normal fibroblasts are maintained without proliferation, whereas those infected with Rous sarcoma virus proliferate rapidly. This proliferative inactivity of normal fibroblasts does not involve contact-inhibition, since the effect is observed at low, as well as higher, culture densities. When a physiological amount of calcium is added to cultures of normal fibroblasts that have been maintained in very low calcium-plasma medium for 3 days, labeled thymidine uptake and protein synthesis are strongly stimulated, and cell division follows. The use of heat-inactivated chicken serum, instead of plasma, in this medium appears to strongly sensitize normal fibroblasts to the mitogenic action of calcium. In a plasma-containing culture medium of physiological calcium concentration and a folate concentration of 5 mug/liter, neither normal nor Rous sarcoma virus-infected fibroblasts proliferate to an appreciable extent. The use of serum, however, instead of plasma results in rapid proliferation of both normal and infected cells, as does increase in the folate concentration of the plasma-containing medium to 100 mug/liter.The fact that while normal fibroblasts are maintained without proliferation in low calcium-plasma medium, Rous sarcoma virus-infected fibroblasts proliferate rapidly, indicates that the effect of calcium is regulatory rather than permissive. These results suggest that the proliferation of normal fibroblasts is initiated by a cellular function involving calcium, and that the autonomous proliferation of the neoplastic fibroblasts results either from increased calcium uptake or from an alteration or a hypass of that function. The results also suggest that serum contains a mitogenic factor(s) not present in plasma, possibly a "wound hormone" for fibroblasts.

Stimulation of the proliferation of chicken fibroblasts by folic acid or a serum factor(s) in a plasma-containing medium.

The proliferation of chicken fibroblasts is strongly stimulated by folic acid, at greater than physiological concentrations, in a plasma-containing medium, or by serum in a medium of physiological folic acid concentration. Serum and plasma, however, do not appear to differ in their content of folic acid derivatives.A qualitative difference between the proliferative behaviors of normal and transformed fibroblasts is obtained when these cells are cultivated in a physiological-folate-low-calcium-plasma medium. In such a medium, transformants proliferate steadily, at a significant rate, while normal fibroblasts do not multiply at all.

Calcium as a regulator of the proliferation of normal, but not of transformed, chicken fibroblasts in a plasma-containing medium.

In a culture medium of low calcium concentration containing 5% heat-inactivated chicken plasma, normal chicken fibroblasts divide very slowly, while their counterparts transformed with Schmidt-Ruppin Rous sarcoma virus divide much more rapidly. In the same low-calcium medium, the use of heat-inactivated serum, rather than heat-inactivated plasma, results in rapid division of both normal and transformed cells. The use of heat-inactivated plasma rather than serum, and the use of a low-calcium medium, combine to permit the demonstration of a marked difference between the proliferative behaviors of normal and neoplastic cells and suggest a basis for the autonomy of the latter.