Transformation of normal diploid cells by isolated metaphase chromosomes of virus-transformed or spontaneous tumor cells.

Normal diploid human cells with a limited life-span in culture, as well as primary or secondary cell cultures of mouse or rat embryos, can be transformed in vitro (i.e. grow in soft-agar or low-serum medium) after a single exposure to metaphase chromosomes from SV40-transformed human or rat cells, Ad5-transformed human cells and several spontaneous human or mouse tumor cells. Chromosomes from normal diploid cells do not show any such transforming activity. As judged from the number of colonies formed in selective medium, the efficiency of transformation is, with some exceptions, of the order of 10(-5)--10(-6) and is generally higher for homologous than for heterologous transfers. A fraction of the colonies demonstrate abortive transformation. Nevertheless, using chromosomes from all but one donor cell population, at least one transferent cell line expressing a stable transformed phenotype has been established. Our results demonstrate that transformation of normal diploid cells by a presumptive chromosome-mediated gene transfer can be obtained with a variety of donor and recipient cells.     

Spontaneous, in vitro, Malignant Transformation of a Basophil/Mast Cell Line

Abstract. It has recently become possible to grow basophil/mast cells in vitro for extended periods of time. Normally, these cultures remain fully dependent upon the presence of an adequate supply of growth factor(s) and the cells express several basophil/mast cell differentiated traits. We report here a case of spontaneous, in vitro, malignant transformation of such a basophil/mast cell line. The transformed cells no longer require the addition of growth factor(s) for continuous proliferation in vitro, and they have become highly tumorigenic in vivo. In contrast, when compared to their untransformed counterparts, they display the same set of differentiated traits, characteristic of immature basophil/mast cells. Thus, the data support the hypothesis that cell transformation results from a decreased sensitivity of precursor cells toward normal growth regulators but does not affect significantly the expression of differentiated functions.     

Spontaneous, in vitro, malignant transformation of a basophil/mast cell line

It has recently become possible to grow basophil/mast cells in vitro for extended periods of time. Normally, these cultures remain fully dependent upon the presence of an adequate supply of growth factor(s) and the cells express several basophil/mast cell differentiated traits. We report here a case of spontaneous, in vitro, malignant transformation of such a basophil/mast cell line. The transformed cells no longer require the addition of growth factor(s) for continuous proliferation in vitro, and they have become highly tumorigenic in vivo. In contrast, when compared to their untransformed counterparts, they display the same set of differentiated traits, characteristic of immature basophil/mast cells. Thus, the data support the hypothesis that cell transformation results from a decreased sensitivity of precursor cells toward normal growth regulators but does not affect significantly the expression of differentiated functions.     

A factor present in fetal calf serum enhances oncogene-induced transformation of rodent fibroblasts.

Our previous studies indicated that addition of the tumor promoters 12-O-tetradecanoylphorbol-13-acetate (TPA) or teleocidin to Dulbecco modified Eagle medium supplemented with calf serum enhanced T24-induced focus formation in both the murine C3H 10T1/2 and rat 6 embryo fibroblast cell lines. In the present studies we have found that fetal calf serum (FCS) is more potent than 12-O-tetradecanoylphorbol-13-acetate in enhancing T24-induced focus formation, in terms of the number and size of the foci, in both C3H 10T1/2 and rat 6 cells. Time course studies indicate that FCS can exert this enhancing effect when it is added several days after the transfection with T24 DNA. In rat 6 cells, an 11-fold increase in T24-induced focus formation occurred when the transfected cultures were maintained for only 1 day in 5% FCS, starting 4 days after the transfection. Several known growth factors, including epidermal growth factor, transforming growth factors alpha and beta, insulin, and platelet-derived growth factor, did not enhance T24-induced transformation in these cell systems. Fractionation studies indicate that the factor present in FCS has a molecular weight of about 1,300, is not lipid soluble, and is acid, base, and heat stable. These findings suggest that a factor(s) normally present in serum may enhance the emergence of tumor cells in vivo, by acting in concert with an activated oncogene, during the multistage carcinogenic process.     

Cytomorphological charasteristics of a novel mouse cell line G1

Growth and morphological properties of a novel mouse cell line G1 have been investigated. It has been shown that cells of this cell line possess the ability of spontaneous transformation in vitro: the cells have unlimited growth in culture, grow in medium with a low serum content and form multilayer colonies on a cell monolayer and cell colonies inside agar. Using micronucleus test it has been revealed that cells of the G1 cell line possess different forms of aberrant mitosis. The results indicate the neoplastic G1 cell transformation with aberrant mitosis.     

Angiogenesis-inducing ability of human bladder epithelium cell lines and "spontaneously" transformed murine fibroblasts

Ten human bladder epithelium cell lines were tested for their ability to induce blood vessel formation after intradermal injection into irradiated ST/a mice. Cell lines that were shown to be tumorigenic in nude mice, were able to evoke angiogenesis of a higher intensity than nontumorigenic cell lines. No difference was observed between the angiogeneic ability of tumorigenic cells originating from tumors and from in vitro transformed urothelium of nontumor origin. Similarly the origin of nontumorigenic urothelial cell lines did not show any influence on their angiogeneic abilities, but nontumorigenic cell lines which had undergone "infinite growth transformation" exhibited a higher angiogeneic activity than nontumorigenic cell lines with a finite life. The angiogeneic reaction evoked by human bladder epithelium cell lines showed cell dose- and time-dependence; but it was unrelated to the growth potential of the cultured cells. Two "spontaneously" altered sarcoma-producing murine cell lines showed a higher angiogeneic activity than tumorigenic human bladder epithelial cells. The angiogeneic response to these two murine cell lines was unrelated to morphological signs of transformation and to differences in growth rate, serum requirement, saturation density, anchorage dependence, and isoimmunizing properties.     

The fate of the primary diploid population during spontaneous transformation of growth factor-supplemented murine cell cultures

Primary cultures derived from lung and renal tissue of the newborn harvest mouse (Micromys minutus) were serially passaged in media supplemented with epidermal growth factor, hydrocortisone, transferrin, insulin, and triiodothyronine. Although these growth factor supplements eliminated the growth crisis commonly encountered during the initial stages of murine primary cultures, the original diploid cell fraction clearly underwent such a "crisis"; the truly diploid cells invariably disappeared as these cultures reached 20 to 40 population doublings. They were replaced, either gradually or precipitously, by various heteroploid cell fractions. In three of four independent cultures, these "established" cells were hypotetraploid and appeared to be derived from a small number of progenitors already present during the very early (precrisis) culture stages. In contrast to rather frequent DNA changes displayed by clones and subclones derived from the various heteroploid cell lineages, the predominant components of the established mass cultures displayed a highly constant DNA fluorescence pattern. Our results suggest that primary murine cell cultures develop heteroploid cell lineages even if the initial growth crisis is mitigated by growth factor supplements. These heteroploid cells appear to respond more efficiently to stimulation by various growth factors than the primary diploid cell population.     

Interaction of serum and colony-stimulating factor for survival of a factor-dependent hemopoietic progenitor cell line

The growth in vitro of the murine myeloid cell line FDC-P1 depends on the presence of serum and a murine hemopoietic growth factor (either granulocyte/macrophage colony-stimulating factor (GM-CSF) or multipotential colony-stimulating factor (multi-CSF, IL3]. To determine the differential roles of serum and colony-stimulating factor (CSF) during the growth of FDC-P1 cultures, we investigated the kinetics of proliferation and death after withdrawal of serum or CSF, using flow cytometry to quantitate the numbers of vital and dead cells. After withdrawal of CSF, the cells died without entering a quiescent state. The life span of cultures lacking CSF increased with increasing concentrations of serum (greater than 50 h at 30% serum), and the cells kept dividing until they died. During the period of population death caused by the absence of CSF, the re-addition of CSF immediately prevented further cells from dying. After the withdrawal of serum in the presence of CSF, the cells continued to live and proliferate for weeks, but required high cell densities (much greater than 10(5)/ml), which suggests that the cells produced an active substance that can substitute for serum. Serum as well as serum-free conditioned medium from dense cultures made the survival and growth of FDC-P1 cultures independent of cell density. Without sufficient quantities of this activity, all cells of the population died within an interval that was much shorter than one cell cycle, which indicates that the factor acts throughout most of the cell cycle. The results suggest that both the CSF and the serum factor act together to permit cell survival, rather than to drive proliferation.     

Transforming viruses directly reduce the cellular growth requirement for a platelet derived growth factor

Early passage mouse embryo fibroblasts, mouse 3T3 cell lines, and early passage diploid human fibroblasts grew to higher cell densities in tissue culture medium supplemented with serum than in medium supplemented with defibrinogenated platelet-poor plasma (PPP). Unlike the mouse cells, the human fibroblasts displayed this differential growth response only in the presence of hypophysiologic concentrations of calcium. The addition of heat-treated extracts of human platelets to PPP-supplemented medium stimulated the replication of both the normal mouse cells and early passage human embryo fibroblasts. Human or mouse fibroblasts transformed by either retroviruses or by SV40, including SV40 infected “serum revertants” and “flat transformants,” grew to equal cell densities in medium supplemented with either serum or PPP. Infection of Balb/c-3T3 cells with SV40 rapidly induced them to grow in PPP-supplemented medium demonstrating that the ability of SV40-transformed cell lines to proliferate in PPP-supplemented medium does not arise from the cell culture selection procedures usually employed to obtain stable virus-transformed cell lines. 3T3 cells infected but not transformed by retroviruses do not replicate in PPP-supplemented medium demonstrating that reduction of the growth requirement for the platelet growth factor(s) by retroviruses is a transformation-specific response. Cell cultures that did not proliferate well in PPP-supplemented medium did not form tumors when inoculated into athymic nude mice. Many, although not all, of the lines which grew well in PPP medium were tumorigenic in nude mice. Together, these findings indicate that: (1) normal fibroblast-like cells display a growth requirement for factor(s) present in serum but not found in PPP; (2) this serum specific growth factor is derived from platelets; (3) a primary response to viral transforming genes is a reduction in the growth requirement for these platelet-derived factors; and (4) cells that have a reduced requirement for the platelet-derived growth factor are often tumorigenic.     

Human umbilical cord blood serum promotes growth, proliferation, as well as differentiation of human bone marrow-derived progenitor cells

Summary Felal calf serum (FCS) is conventionally used for animal cell cultures due to its inherent growth-promoting activities. However animal welfare issues and stringent requirements for human transplantation studies demand a suitable alternative for FCS. With this view, we studied the effect of FCS, human AB serum (ABS), and human umbilical cord blood serum (UCBS) on murine islets of Langerhans and human bone marrow-derived mesenchymal-like cells (hBMCs). We found that there was no difference in morphology and functionality of mouse islets cultured in any of these three different serum supplements as indicated by insulin immunostaining. A comparative analysis of hBMCs maintained in each of these three different serum supplements demonstrated that UCBS supplemented media better supported proliferation of hBMCs. Moreover, a modification of adipogenic differentiation protocol using UCBS indicates that it can be used as a supplement to support differentiation of hBMCs into adipocytes. Our results demonstrate that UCBS not only is suitable for maintenance of murine pancreatic islets, but also supports attachment, propagation, and differentiation of hBMCs in vitro. We conclude that UCBS can serve as a better serum supplement for growth, maintenance, and differentiation of hBMCs, making it a more suitable supplement in cell systems that have therapeutic potential in human transplantation programs.     

T cells and the anti-trinitrophenyl antibody response to fetal calf serum and 2-mercaptoethanol

Unprimed murine lymphocytes maintained in culture medium containing fetal calf serum (FCS) and 2-mercaptoethanol (2-ME) developed very high levels of anti-trinitrophenyl (TNP) plaque forming cells (PFC). Both FCS and 2-ME contributed to the response. The development of anti-TNP PFC during culture was accompanied by a 10-fold expansion in the number of immunoglobulin-secreting cells, indicating polyclonal stimulation. However, the number of anti-TNP PFC was disproportionately high and not accompanied by a similar increase in plaques specific for sheep red blood cells. The TNP-specific plaques were not artifacts of the plaque assay since they were 98% inhibited by specific antigen. The in vitro induction of anti-TNP PFC by FCS and 2-ME was common to a number of mouse strains, although some genetic variation occurred. Nylon-wool-separated B cells, nude mouse spleen cells, and bone marrow cells all produced high levels of anti-TNP after culture with medium containing FCS and 2-ME. The addition of T cells to B-cell cultures increased the numbers of anti-TNP PFC by 1.5- to 2.5-fold. The presence of a TNP-cross-reacting antigen in FCS probably contributed to the unexpectedly high anti-TNP response. The response to the antigen in FCS was potentiated by the enhancing activity of 2-ME.     

Alterations in pH and Serum Concentration have Contrasting Effects on Normal and "Foreign" Pathways of Differentiation in Cultures of Embryonic Chick Neuroretinal Cells

Nine-day chicken embryo neuroretinal cells transdifferentiate into both lens and pigment cells after 3–4 weeks when cultured in MEM medium containing 10% foetal calf serum at pH 7.4. At pH 6.8. the appearance of lens crystallins is retarded and cholineacetyltransferase (CAT) activity persists for longer, whereas at pH 8.0 crystallins appear earlier and CAT activity declines more rapidly. Cell survival and culture growth are about 10% lower at pH 6.8 than at pH 8.0. If the concentration of foetal calf serum (FCS) is increased from 10% to 25% (at pH 7.4), cell survival and growth are both promoted, crystallins appear slightly earlier and CAT activity declines more rapidly. Converse effects are observed with 5 % serum, accumulation of crystallins being greatly inhibited and CAT activity prolonged. Crystallin production in cultures with 10% or 25% chicken serum (CS) is much less extensive than in similar FCS cultures, but in cultures with 5 % CS, crystallins appear more rapidly, reaching higher levels than in 5 % FCS cultures. However, the pattern of CAT activity in response to different serum levels is similar for both CS and FCS. This might imply the presence of some factor(s) able to stimulate transdifferentiation in FCS, whereas CS can apparently inhibit this process.     

The capacity of fetal calf serum to support a primary antibody response in vitro is determined,in part,by its reduced glutathione content

Fetal calf serum (FCS) is unique among mammalian sera in its ability to support a primary antibody response, in vitro, by murine spleen cells. Another property unique to FCS among mammalian sera is its content of the tripeptide, glutathione. Since glutathione has a number of physiological functions important to cell function and survival, we have studied the possible relationship between the glutathione content of FCS and the ability of FCS to support a primary antibody response, in vitro. Our findings indicate that the capacity of FCS to support the murine spleen cell primary antibody response, in vitro, is, in part a function of its reduced glutathione (GSH) content, since: (a) GSH concentration correlates directly and definitively with the capacity of a lot of FCS to support an antibody response; (b) oxidation of GSH by heating a supportive FCS diminishes the supportive capacity of that FCS; and (c) such a treated FCS can be reconstituted to full supportiveness by appropriate doses of GSH. We postulate that reduced glutathione achieves this effect by scavenging lipid hydroperoxides generated by the action of oxygen-derived free radicals in the cell cultures.     

Differential effects of transforming growth factor-beta and epidermal growth factor on the cell cycle of cultured rabbit articular chondrocytes

We examined the effect of transforming growth factor (TGF-beta) on the proliferative rate and cell cycle of cultured rabbit articular chondrocytes using cell counting, cytofluorometry, and [3H]-thymidine incorporation. In the presence of 2% or 10% FCS (fetal calf serum), TGF-beta at 0.01, 0.1, 1, and 10 ng/ml had an inhibitory effect on cell proliferation after 24 h exposure with a dose dependence only for 2% FCS. Flow cytometric analysis of cell DNA content at that time showed that a high proportion of cells were arrested in late S-phase (SQ or G2Q) in either 2% or 10% FCS-containing medium. In both cases, a disappearance of the cell blockage occurred between 24 and 48 h after TGF-beta addition. However, whereas a stimulation of cell proliferation rate was observed at that time in cultures containing 10% FCS, a dose-dependence inhibition of cell growth was detected, in contrast, for 2% FCS-treated cells. Presence of TGF-beta during the last 24 h was not necessary to release the arrested cells. Furthermore, platelet-poor plasma at 10% produced the same effects as FCS, suggesting that platelet-derived factors, such as platelet-derived growth factor (PDGF), could not be responsible for the release of blocked cells in this case. We compared the effect of TGF-beta to that of epidermal growth factor (EGF), used at an optimal concentration (10 ng/ml). In both slowly growing (2% FCS) and proliferating chondrocytes (10% FCS), EGF caused a significant increase of cell proliferation as early as 24 h. No arrest in late S-phase but an augmentation of the percentage of cells in S- and G2M-phases were observed. When combined, TGF-beta and EGF did not induce synergistic effect on the chondrocyte proliferation, as estimated by cell counting. [3H]-thymidine labeling showed that the factors induced identical maxima of incorporation but the peak occurred earlier for TGF-beta than for EGF (approximately 6 h versus 12 h, respectively). Although both factors induce similar cell-number increases at 48 h in 10% FCS-containing medium, these proliferative effects were due to different actions on the cell cycle. The present study indicates that TGF-beta induces first a recruitment of chondrocytes in noncycling SQ- or G2Q-blocked cells. The, the release of these cells may produce either apparent stimulation of cell proliferation if sufficient levels of an unknown serum factor are present (10% FCS) or an inhibition of growth rate when only reduced amounts of this factor are available (2% FCS).(ABSTRACT TRUNCATED AT 400 WORDS)     

Malignant transformation of murine fibroblasts by a human c-Ha-ras-1 oncogene does not require a functional epidermal growth factor receptor.

Although mutations in ras genes are thought to be important for the development of about 20% of human tumors, almost nothing is known about the way in which these mutations lead to cellular transformation. The known biochemical properties of the 21-kilodalton ras proteins suggest that they may behave as G proteins, regulating the proliferation of cells in response to growth factor stimulation of a receptor. Although the putative receptor(s) has not been identified, several lines of evidence, in particular the fact that rodent cell lines containing ras oncogenes produce transforming growth factor alpha, have suggested that the epidermal growth factor (EGF) receptor is involved in ras transformation. Here we show that murine fibroblasts with no EGF receptors can be transformed to a completely malignant phenotype with a mutated ras gene. It appears, therefore, that the EGF receptor is not required for ras-mediated transformation of these cells.     

Spontaneous cell transformation: karyoplasts derived from multinucleated cells produce new cell growth in senescent human epithelial cell cultures

Previously, it was shown that SV40-induced cell transformation of human diploid (2N), epithelial cells was a dynamic process of nuclear and cellular events. In this process, nuclei of polyploid (above 2N) cells broke down into multinucleated cells (MNCs) by amitotic division. An induced mass karyoplast (i.e., small cell with reduced amount of cytoplasm) budding process from the MNCs produced transformed cells with extended life span (EL) and altered morphology. In this study, without the use of SV40 and no induction of karyoplast budding, the same sequence of cellular events was found to occur spontaneously for the same type of cells at replicative senescence (no mitosis). These cell transformation events were followed by phase-contrast photography of living cell cultures. Primary, diploid, epithelial cell cultures grew for two to three passages and then entered senescence. Cells remaining in the cultures after widespread cell death (mortality stage 1; M1) developed the typical large, flat-cell morphology of senescence with increased cytoplasmic volume. Some of these cells were MNCs, mostly with two to four nuclei. Cytokinesis in MNCs and spontaneous karyoplast budding from MNCs were observed, and new, limited EL cell growth was present either in foci of cells or as prolonged cell growth over one to two passages. At the end of their replicative phase, the EL cells entered another death crisis (M2) from which no cells survived. In M2-crisis, rarely transformed cells appear with immortal cell growth characteristics (i.e., cell lines). Numerous examples of fragmentation or amitosis of polyploid nuclei in the production of multinucleated cells (MNCs) are presented. Such nuclear divisions produced nuclei with unequal sizes, which suggest unbalanced chromosomal segregations. The nuclear and cellular events in cell transformation are compared with a natural (no induction) occurrence of MNC-offspring cells in mammalian placentas. The possibility of a connection between these two processes is discussed. And finally the difference in the duration of EL cell growth from SV40-MNCs versus from senescent-MNCs is ascribed to increased mutational load in SV40-induced MNCs as compared with that in senescence MNCs.     

Altered cell cycle responses to insulin-like growth factor I, but not platelet-derived growth factor and epidermal growth factor, in senescing human fibroblasts

Human diploid fibroblasts (HDF) were used to study aging-related changes in the proliferative response to platelet-derived growth factor (PDGF), epidermal growth factor (EGF), and insulin-like growth factor I (IGF-I, somatomedin-C) in serum-free, chemically defined culture medium. Cell cycle kinetic parameters were determined by using 5-bromodeoxyuridine incorporation and flow cytometric analysis with the DNA stain Hoechst 33258. This allowed analysis of the growth factor response to be focussed exclusively upon of the cycling faction of cells within the culture, even in senescent cell cultures which contained predominantly nondividing cells. PDGF and EGF exert their primary effect upon regulation of the proportion of cycling cells in the culture. The doses of PDGF and EGF that produced a half-maximal cycling fraction, analogous to Km, showed no large or consistent difference between young- and old-passage cells. In contrast, IGF-I primarily affects the rate of transition of cells from G1 into S phase, and the dose of IGF-I which produced a half-maximal rate of G1 exit increased up to 130-fold in older-passage cells. Unexpectedly, supraphysiologic concentrations of IGF-I were found to increase the G1 exit rate of the dividing subpopulation of cells in older-passage cultures to rates higher than those seen in young cultures. In summary, among cells capable of cycling in aging cultures, there were few changes in the regulation of the growth fraction by PDGF and EGF, but there was a greatly increased dependence on IGF-I for regulation of the rate of entry into S phase. The slower growth of the dividing population of cells in aging cultures may be related to a requirement for IGF-I at levels which are greatly above those usually supplied.     

Immortalization of human urothelial cells by human papillomavirus type 16 E6 and E7 genes in a defined serum-free system

Normal human epithelial cell cultures exhibit a limited (although different between tissues) lifespan in vitro. In previous studies, urothelial cell cultures were immortalized using retroviral transformation with human papillomavirus type 16 E6 and E7 genes, in undefined culture systems containing serum or bovine pituitary extract. OBJECTIVE: Due to the variability of results in such systems, we instead developed a procedure for the immortalization of urothelial cells using a defined, serum-free culture system. METHOD AND RESULTS: Immortalization through retroviral transformation with human papillomavirus type 16 E6 and E7 was successful, and transformation of urothelial cells conferred an extended over normal lifespan and restored telomerase activity. Transformed cells retained typical morphology and exhibited a similar growth rate, cytokeratin immunoreactivity pattern, and response to growth factors as observed in untransformed cells. Karyotype analysis revealed a gradual accumulation of genetic mutations that are consistent with previously reported mutations in epithelial cells transformed with human papillomavirus type 16 E6 and E7. CONCLUSION: The ability to extend the in vitro lifespan of cells holds the potential to reduce the continuous need for tissue samples and to enable complete investigations with one cell line.     

C127 cells resistant to transformation by tyrosine protein kinase oncogenes

C127 is a nontumorigenic mouse cell line widely used in in vitro transformation assays due to its normal morphological appearance and its very low levels of spontaneous transformation. We now report that C127 cells are resistant to transformation by tyrosine protein kinase oncogenes derived from growth factor receptors such as the retroviral v-fms and the human trk transforming genes. In contrast, these cells could be efficiently transformed by members of the ras oncogene family and by serine/threonine kinase oncogenes such as v-mos and v-raf. C127 cells were also found to be resistant to transformation by v-src, the prototype of a large family of tyrosine protein kinase oncogenes whose products are associated with the inner side of the plasma membrane. However, morphologically normal C127 cells expressing pp60v-src acquired a transformed phenotype upon continuous passage in vitro. Somatic cell hybrids (neoR, hygroR) obtained by fusion of G418-resistant C127 cells expressing p70trk (neoR) and hygromycin-resistant NIH3T3 cells (hygroR) exhibited transformed properties as determined by their ability to grow in semisolid agar. In contrast, no such growth was observed when these neoR p70trk-containing C127 cells were fused to control hygroR C127 cells. These results indicate that C127 cells may either lack or express insufficient levels of certain critical substrate(s) necessary for the onset of transformation by tyrosine protein kinase oncogenes.     

Cellular responsiveness to growth factors correlates with a cell's ability to express the transformed phenotype

Five random subclones of the rat fibroblast line F2408 vary in their frequency of transformation by the unrelated Kirsten murine sarcoma virus and Abelson murine leukemia virus. The same pattern of sensitivity is displayed when the cells are induced to anchorage-independent growth (transformed) by epidermal, platelet-derived, and sarcoma growth factors, or by whole serum. Our results demonstrate that a growth factor's ability to render cells anchorage independent is not unique to transforming growth factors, but common to many growth factors; anchorage-independent growth is a function of the total growth factor concentration in the medium; cells vary in their inherent responsiveness to growth-factor-induced anchorage-independent growth; and cells resistant to growth-factor-induced anchorage-independent growth are also resistant to transformation by a variety of tumor viruses. We conclude that the way a cell responds to growth factors plays a central role in the expression of the transformed phenotype.