Immortalization by c-myc, H-ras, and Ela oncogenes induces differential cellular gene expression and growth factor responses.

Early-passage rat kidney cells were immortalized or rescued from senescence with three different oncogenes: viral promoter-driven c-myc, H-ras (Val-12), and adenovirus type 5 E1a. The normal c-myc and H-ras (Gly-12) were unable to immortalize cells under similar conditions. Quantitation of RNA in the ras-immortalized lines demonstrated that the H-ras oncogene was expressed at a level equivalent to that of the normal H-ras gene in established human or rat cell lines. Cell lines immortalized by different oncogenes were found to have distinct growth responses to individual growth factors in a short-term assay. E1a-immortalized cells were largely independent of serum growth factors, whereas c-myc-immortalized cells responded to serum better than to epidermal growth factor and insulin. H-ras-immortalized cells responded significantly to insulin alone and gave a maximal response to epidermal growth factor and insulin. Several cellular genes associated with platelet-derived growth factor stimulation, including c-myc, were expressed at high levels in the H-ras-immortalized cells, and c-myc expression was deregulated, suggesting that the H-ras oncogene has provided a "competence" function. H-ras-immortalized cells could not be morphologically transformed by secondary transfection with a long terminal repeat-c-myc oncogene, but secondary transfection of the same cells with H-ras (Val-12) produced morphologically transformed colonies that had 20- to 40-fold higher levels of H-ras oncogene expression. Thus, transformation in this system is dependent on high levels of H-ras oncogene expression rather than on the presence of activated H-ras and c-myc oncogenes in the same cell.     

The oncogenic forms of N-ras or H-ras prevent skeletal myoblast differentiation.

Differentiation of skeletal muscle involves withdrawal of myoblasts from the cell cycle, fusion to form myotubes, and the coordinate expression of a variety of muscle-specific gene products. Fibroblast growth factor and type beta transforming growth factor specifically inhibit myogenesis; however, the transmembrane signaling pathways responsible for suppression of differentiation by these growth factors remain elusive. Because ras proteins have been implicated in the transduction of growth factor signals across the plasma membrane, we used DNA-mediated gene transfer to investigate the potential involvement of this family of regulatory proteins in the control of myogenesis. Transfection of the mouse skeletal muscle cell line C2 with the oncogenic forms of H-ras or N-ras completely suppressed both myoblast fusion and induction of the muscle-specific gene products nicotinic acetylcholine receptor and creatine kinase. Inhibition of differentiation by activated ras genes occurred at the level of muscle-specific mRNA accumulation. In contrast, proto-oncogenic forms of N-ras or H-ras had no apparent effects on the ability of C2 cells to differentiate. Myoblasts transfected with activated ras genes exhibited normal growth properties and ceased proliferating in the absence of mitogens, indicating that ras inhibited differentiation through a mechanism independent of cell proliferation. These results demonstrate that activated ras gene products mimic the inhibitory effects of fibroblast growth factor and type beta transforming growth factor on myogenic differentiation and suggest that each of these regulators of myogenesis may operate through a common intracellular pathway.     

Suppression of the EGF-dependent induction of c-myc proto-oncogene expression by transforming growth factor beta in a human breast carcinoma cell line

Alterations in c-myc proto-oncogene expression after treatment of human mammary carcinoma MDA-468 cells with epidermal growth factor (EGF) and/or transforming growth factor beta (TGF beta) have been investigated. A stimulation of c-myc messenger RNA was detected within 60 min after treatment with EGF. This induction persisted for at least 24 hr, albeit to a lower extent. The early and late increase in c-myc mRNA levels induced by EGF were inhibited by the presence of TGF beta. TGF beta alone induced little change in c-myc mRNA levels. The effect of TGF beta represents a novel action of this hormone at the level of gene expression.     

Inhibition of myogenic differentiation by fibroblast growth factor or type beta transforming growth factor does not require persistent c-myc expression

Skeletal muscle differentiation is accompanied by accumulation of the mRNA encoding the muscle isoenzyme of creatine kinase (MCK) and can be suppressed by serum components, fibroblast growth factor (FGF), or type beta transforming growth factor (TGF beta). Using the nonfusing myogenic cell line, BC3H1, the potential involvement of c-myc in growth factor-dependent inhibition of myogenesis was examined. Withdrawal of undifferentiated myoblasts from the cell cycle in medium with 0.5% serum was associated with a precipitous decline in expression of c-myc mRNA followed by induction of MCK mRNA. In 0.5% serum containing TGF beta, c-myc mRNA declined to a level identical to that in differentiated cells; however, MCK mRNA was not expressed. Exposure of quiescent differentiated cells to FGF or TGF beta caused disappearance of muscle-specific gene products and was accompanied by only transient low level induction of c-myc mRNA. These data indicate that persistent c-myc expression is not required for growth factor-mediated inhibition of myogenic differentiation.     

Survey of oncogene and growth factor/receptor gene expression in cancer cells by intron-differential RNA/PCR.

To elucidate the possible roles of proto-oncogenes and growth factors in estrogen-regulated cell proliferation of human breast and gynecologic cancers, we have determined the gene expressions of c-myc, transforming growth factor-alpha and beta 1 (TGF-alpha, beta 1) and epidermal growth factor receptor (EGFR) in a number of these cancer cell lines by using an intron-Differential (ID) RNA/PCR method, which differentially identifies the amplified cDNA from PCR products of genomic DNA contaminants. With this method, we demonstrated the expression of these genes, except EGFR, in an estrogen-dependent breast cancer cell line (CAMA-1). Our results show that TGF-alpha/EGF does not function as an autocrine factor in this cell line. Accordingly, it is unlikely that the TGF-alpha/EGFR system participates as a mediator in the estrogen-induced cell proliferation of CAMA-1 cells. The ID RNA/PCR method is a rapid, sensitive and specific technique for mRNA phenotyping and will have great clinical utility.     

The novel primary response gene MyD118 and the proto-oncogenes myb, myc, and bcl-2 modulate transforming growth factor beta 1-induced apoptosis of myeloid leukemia cells.

Cell numbers are regulated by a balance among proliferation, growth arrest, and programmed cell death. A profound example of cell homeostasis, controlled throughout life, is the complex process of blood cell development, yet little is understood about the intracellular mechanisms that regulate blood cell growth arrest and programmed cell death. In this work, using transforming growth factor beta 1 (TGF beta 1)-treated M1 myeloid leukemia cells and genetically engineered M1 cell variants, the regulation of growth arrest and apoptosis was dissected. Blocking of early expression of MyD118, a novel differentiation primary response gene also shown to be a primary response gene induced by TGF beta 1, delayed TGF beta 1-induced apoptosis, demonstrating that MyD118 is a positive modulator of TGF beta 1-mediated cell death. Elevated expression of bcl-2 blocked the TGF beta 1-induced apoptotic pathway but not growth arrest induced by TGF beta 1. Deregulated expression of either c-myc or c-myb inhibited growth arrest and accelerated apoptosis, demonstrating for the first time that c-myb plays a role in regulating apoptosis. In all cases, the apoptotic response was correlated with the level of MyD118 expression. Taken together, these findings demonstrate that the primary response gene MyD118 and the c-myc, c-myb, and bcl-2 proto-oncogenes interact to modulate growth arrest and apoptosis of myeloid cells.     

An altered repertoire of fos/jun (AP-1) at the onset of replicative senescence.

With multiple divisions in culture, normal diploid cells suffer a loss of growth potential that leads to replicative senescence and a finite replicative capacity. Using quantitative RT-PCR, we have monitored mRNA expression levels of c-fos, c-jun, JunB, c-myc, p53, H-ras, and histone H4 during the replicative senescence of human fibroblasts. The earliest and the largest changes in gene expression occurred in c-fos and junB at mid-senescence prior to the first slowing in cell growth rates. The basal level of c-fos mRNA decreased to one-ninth that of the early-passage levels, while junB declined to one-third and c-jun expression remained constant. The decline in the basal c-fos mRNA level in mid-senescence should lead to an increase in Jun/Jun AP-1 homodimers at the expense of Fos/Jun heterodimers and may trigger a cascade of further changes in c-myc, p53, and H-ras expression in late-passage senescent fibroblasts.     

Enhanced growth-dependent expression of TGF beta 1 and hsp70 genes in aortic smooth muscle cells from spontaneously hypertensive rats.

Enhanced proliferation of vascular smooth muscle cells (VSMC) from spontaneously hypertensive rats (SHR) as compared with Wistar-Kyoto rats (WKY) persists in long-term culture and is characterized by an accelerated entry of these cells into the synthetic S phase of the cell cycle and a higher specific growth rate, particularly evident at high cell density. In the present study, we investigated by Northern blot experiments the expression of genes putatively involved in the regulation of VSMC growth. One of them is the transforming growth factor beta 1 gene (TGF beta 1), a bifunctional modulator of cell growth whose action is dependent on cell density. The accumulation of TGF beta 1 mRNA was enhanced in growing SHR cells at every density studied as early as 24 h after inoculation with a further increase at later times. Protooncogenes c-fos and c-myc, which have been implicated in G1/S phase transition, have also been investigated in VSMC by Northern blot analysis. At low cell density, calf serum stimulated c-fos and c-myc mRNA expression was comparable in WKY and SHR cells whereas at high cell density, c-fos induction was higher in VSMC from SHR. SHR VSMC respond more to mitogenic stimulation and to environmental (e.g., heat) stress, particularly when growing near saturation density. hsp70 constitutes a gene family responsive to environmental stimuli (heat) and to mitogenic stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for c-myc in the signaling pathway for TGF-beta in well-differentiated human colon carcinoma cells

Previously, we described a model culture system for comparing responsiveness of poorly differentiated and well-differentiated human colon carcinoma cells to exogenous growth factors. While polypeptide growth stimulators elicited an up-regulation of c-myc, as well as a mitogenic response in the well-differentiated cells, the poorly differentiated cells were insensitive to exogenous growth stimulators. We now show, by thymidine incorporation experiments and autoradiographic analysis, that transforming growth factor beta 1 (TGF-beta) abrogated the mitogenic responses to the growth factors epidermal growth factor + insulin + transferrin (IC50 = 0.8 ng/ml), as well as to nutrients (basal medium; IC50 = 0.2 ng/ml) in the well-differentiated cells. The poorly differentiated cells did not respond to TGF-beta. Moreover, TGF-beta (10 ng/ml) completely abrogated the growth factor-stimulated up-regulation of c-myc in the TGF-beta responsive, well-differentiated colon carcinoma cells. Addition of TGF-beta to the TGF-beta-responsive, well-differentiated cells, at a time after c-myc had been transiently up-regulated in response to growth stimulatory factors, resulted in a loss of responsiveness to TGF-beta. Addition of TGF-beta to these cells at increasing time periods after EIT stimulation also resulted in a loss of the TGF-beta-induced repression of c-myc. The results suggest an important role for c-myc in the mechanism of action of TGF-beta in well-differentiated human colon carcinoma cells.     

Cadmium produces a delayed mitogenic response and modulates the EGF response in quiescent NRK cells

Recent studies have shown that cadmium, at subtoxic levels, may induce a response characteristic of that elicited by a type of growth factor that supports the anchorage independent growth of cells that are not fully transformed. That is, Cd⁺⁺ was found to replace transforming growth factor beta in supporting soft agar growth of NRK-49F cells. To tes the extent to which Cd⁺⁺ further mimics transforming growth factor beta in its effects and to establish response patterns that suggest possible molecular mechnisms of action, we have determined the effects of Cd⁺⁺ and/or epidermal growth factor (EGF) on DNA synthesis in quiescent NRK-49F cells. We found that subtoxic doses of Cd⁺⁺ modulate EGF-induced DNA synthesis in a dose-dependent fashion. Although Cd⁺⁺ effects on early (16–24 hr) EGF-induced DNA synthesis are primarily inhibitory, later effects involve stimulation as well. Subtoxic doses of Cd⁺⁺ did not stimulate DNA synthesis in quiescent cells within 24 hr of addition. At later times (40 or 64 hr), however, an increase in DNA synthesis of up to threefold was induced by 0.25 M Cd⁺⁺. This pattern of mitogenic response, involving inhibition of early growth-factor induced DNA synthesis and stimulation of late DNA synthesis, is consistent with that reported to be effected in some instances by transforming growth factor beta. Because a defined pattern of gene expression also is associated with the mitogenic responses to transforming growth factor beta, future studies at the molecular level can definitively test the degree to which Cd⁺⁺ and transforming growth factor beta effects are common.Abbreviations CFE colony forming efficiency - EGF epidermal growth factor - MT metallothionein - PGDF paltelet derived growth factor - TGF transforming growth factor     

Heparin-binding growth factor/prostatropin attenuates inhibition of rat prostate tumor epithelial cell growth by transforming growth factor type beta

Summary Normal rat prostate epithelial cell growth requires both epidermal growth factor and heparin-binding growth factor/prostatropin. In contrast, epithelial cells derived from the transplantable Dunning R3327H rat tumor require either epidermal growth factor or heparin-binding growth factor/prostatropin. Transforming growth factor type beta inhibited normal epithelial cell growth. Transforming growth factor beta inhibited epidermal growth factor-dependent growth of tumor epithelial cells, independent of epidermal growth factor concentrations. Transforming growth factor beta increased the effective dose of heparin-binding growth factor type 1 required to support tumor epithelial cell growth by 10-fold but saturating levels of heparin-binding growth factor type 1 (290 pM) completely attenuated the inhibitory effect of transforming growth factor beta. These results suggest that prostate tumor epithelial cells may escape the inhibitory effect of transforming growth factor beta as a consequence of alteration of the concurrent requirement for both epidermal growth factor (or homologues) and heparin-binding growth factors. This work was supported by NCI Grant CA37589. Editor’s Statement The observation that heparin-binding growth factor/prostatropin can counteract the inhibitory effect of transforming growth factor beta in prostate epithelial cells may help explain how some cancers avoid the action of growth inhibitors and provides a model for studying how inhibitory peptides overcome the stimulatory signals generated by growth factors.     

Antisense inhibition of c-myc expression reveals common and distinct mechanisms of growth inhibition by TGF beta and TNF alpha

Downregulation of the c-myc gene in HL-60 cells is associated with growth inhibition and induction of differentiation. Previous studies have reported that the growth inhibitors TGF beta and TNF alpha downregulate c-myc mRNA levels, suggesting the possibility that these agents may exert some of their phenotypic effects via c-myc downregulation. Our study demonstrates that although both growth inhibitors produce a similar decrease in c-myc protein synthesis, TNF alpha produces a greater growth inhibition and differentiation induction in HL-60 cells. Combined addition of anti-myc oligomer with either growth inhibitor produces no additive effect. In fact, 4 microM anti-myc oligomer produces the same growth and differentiation effects as does 10 ng/ml TGF beta 1. We conclude that downregulation of c-myc expression represents a common mechanism of growth inhibition by TGF beta and TNF alpha, but that TNF alpha possesses an additional effect that is independent of c-myc expression.     

Decreased expressions of c-myc and H-ras oncogenes in vitamin E succinate induced morphologically differentiated murine B-16 melanoma cells in culture

Treatment of B-16 melanoma cells in culture with d-alpha-tocopheryl succinate (vitamin E succinate) at concentrations of 11.3 and 15.1 microM inhibited growth and induced cell differentiation in culture. Vitamin E succinate treatment decreased the levels of c-myc and H-ras specific mRNAs in melanoma cells. Similar results were obtained by the vitamin retinoic acid and the nonvitamin agents R020-1724 (4-(3-butoxy-4-methoxybenzyl)-2-imidazolidinone), an inhibitor of cyclic nucleotide phosphodiesterase (0.72 mM), and sodium butyrate (1 mM), which induced differentiation and (or) inhibited growth of melanoma cells in culture. The extent of inhibition of c-myc mRNA was greater than that of H-ras mRNA. These results indicate that vitamin E succinate induced reduction of the levels of c-myc and H-ras mRNAs is related to growth inhibition of melanoma cells in culture.     

Increased secretion of type beta transforming growth factor accompanies viral transformation of cells.

Cells transformed by Harvey or Moloney sarcoma virus secrete at least 40 times as much type beta transforming growth factor as their respective untransformed control cells. The transformed cells bind only 20 to 50% as much type beta transforming growth factor as the control cells, suggesting that transformation causes down-regulation of the type beta transforming growth factor receptor.     

The role of transforming growth factor beta in atherosclerosis: novel insights and future perspectives

PURPOSE OF REVIEW: Atherosclerosis is a disease of the arterial wall that seems to be tightly modulated by the local inflammatory balance. Transforming growth factors beta 1, 2 and 3 are cytokines/growth factors with broad activities on cells and tissues in the cardiovascular system, and have been suggested to play a role in the pathogenesis of atherosclerosis. RECENT FINDINGS: In the present review, we discuss recent developments in the role of transforming growth factor beta in the regulation of the immuno-inflammatory balance that modulates atherosclerosis. Such studies strongly suggest that the inhibition of endogenous transforming growth factor beta signalling favours the development of atherosclerotic lesions with an increased inflammatory component (T cells and macrophages) and decreased collagen content, features that are characteristic of unstable atherosclerotic plaques. SUMMARY: Transforming growth factor beta is identified as a critical modulator of the immuno-inflammatory balance in atherosclerosis, and a crucial plaque-stabilizing factor. Future studies should aim at defining the precise molecular mechanisms responsible for this protective effect, and developing immunomodulatory strategies based on the promotion of transforming growth factor beta activity (T regulatory T helper type 3 cells) to limit disease complications.