Orthovanadate both mimics and antagonizes the transforming growth factor β action on normal rat kidney cells

Normal rat kidney [NRK] cells grown in the presence of epidermal growth factor (EGF) or platelet-derived growth factor (PDGF) have a normal phenotype and undergo density-dependent growth inhibition, whereas in the presence of multiple growth factors, density arrest is lost and the cells become phenotypically transformed. We studied the influence of the protein tyrosine phosphatease (PTPase) inhibitor sodium orthovanadate on the mitogenic stimulation of NRK cells by growth factors and on transformation-linked properties as loss of density-dependent growth inhibition and anchorage-independent growth. The fraction of cells in serum-deprived monolayer cultures that is induced to proliferate upon mitogenic stimulation by EGF or PDGF is only slightly enhanced upon addition of low concentrations (25–50 μM) of vanadate. Addition of vanadate per se induces proliferation of only a very limited amount of cells, but results in a shift of the dose-response curves for other growth factors to lower concentrations. Vanadate added in combination with EGF or PDGF is able to mimic the effect of transforming growth factor β (TGFβ) in inducing phenotypic transformation. In monolayer cultures density-dependent growth inhibition is lost and anchorage-independent proliferation is observed on dishes coated with poly(2-hydroxy-ethyl methacrylate) (polyHEMA). The extent of these changes is similar to that induced by TGFβ. However, the morphology of the obtained colonies in polyHEMA-coated dishes is quite different. Cells transformed by TGFβ in the presence of EGF form rather amorphous colonies, whereas in the presence of orthovanadate colonies are formed that tend to fall apart in loose cells. The effect of vanadate on cell transformation is dependent on the growth factor conditions in a bimodal way. When a suboptimal dose of growth factor(s) is used, 25 μM vanadate is very effective in preventing density-induced growth inhibition and stimulating anchorage-independent proliferation. However, the same concentration of vandate is inhibitory when cells are maximally stimulated and antagonizes the transforming effect of TGFβ added in combination with other growth factors. It is hypothesized that vanadate acts on a set of different protein tyrosine phosphatases. Some of these are positive and others negative regulators of growth. © 1993 Wiley-Liss, Inc.     

Transforming growth factor-beta and retinoic acid modulate phenotypic transformation of normal rat kidney cells induced by epidermal growth factor and platelet-derived growth factor

In this study we have investigated the ability of epidermal growth factor (EGF), platelet-derived growth factor (PDGF), and transforming growth factor-beta (TGF beta) together with retinoic acid (RA) at saturating concentrations to induce phenotypic transformation of normal rat kidney (NRK) cells in a growth factor-defined medium. This medium contains serum in which all growth factor activity has been chemically inactivated, thereby eliminating the effects of growth factors from serum in the assay. It is shown that neither TGF eta nor a ligand binding to the EGF receptor is essential for phenotypic transformation of NRK cells, since anchorage-independent growth is also induced by EGF in combination with RA and by PDGF in combination with RA and TGF beta. Our data indicate strong similarities between TGF beta and RA in their ability to act as modulators for phenotypic transformation. In addition, both agents enhance the number of EGF receptors in NRK cells, without affecting the number of PDGF receptors. On the other hand, TGF beta has mitogenic effects on a number of non-transformed cell lines, such as Swiss 3T3 fibroblasts, particularly when assayed in the absence of insulin, whereas RA is mitogenic for these cells only in the presence of insulin. These data demonstrate that phenotypic transformation of NRK cells requires specific combinations of polypeptide growth factors and modulating agents, but that this process can be induced under many more conditions than previously described. Moreover, our data point toward both parallels and differences in the activities of TGF beta and RA.     

Phenotypic transformation of normal rat kidney cells by transforming growth factor beta is not paralleled by enhanced production of a platelet-derived growth factor.

Phenotypic transformation of normal rat kidney (NRK) cells requires the concerted action of multiple polypeptide growth factors. Serum-deprived NRK cells cultured in the presence of epidermal growth factor (EGF) become density-inhibited at confluence, but they can be restimulated by a number of defined polypeptide growth factors, resulting in phenotypic cellular transformation. Kinetic data show that restimulation by transforming growth factor beta (TGF-beta) and retinoic acid is delayed when compared to induction by platelet-derived growth factor (PDGF), indicating that both TGF beta and retinoic acid may exert their growth-stimulating action by an indirect mechanism. Northern blot analysis shows that NRK cells express the genes for various polypeptide growth factors, including TGF beta 1, PDGF A-chain and basic fibroblast growth factor, but that the levels of expression are not affected by TGF beta or retinoic acid treatment. NRK cells also secrete low amounts of a PDGF-like growth factor into their extracellular medium, but the levels of secretion are insufficient to induce mitogenic stimulation and are unaffected by agents inducing phenotypic transformation. In combination with studies on the effects of anti-PDGF antibodies, it is concluded that phenotypic transformation of NRK cells by TGF beta and retinoic acid is not the result of enhanced production of a PDGF-like growth factor.     

PDGF-like growth factor induces EGF-potentiated phenotypic transformation of normal rat kidney cells in the absence of TGF beta

Using a growth factor defined assay for anchorage-independent growth (van Zoelen, E.J.J., van Oostwaard, Th.M.J., van der Saag, P.T. and de Laat, S.W. (1985) J. Cell. Physiol. 123, 151- 160, we have studied the ability of polypeptide growth factors produced by Neuro-2A neuroblastoma cells to induce anchorage-independent growth of normal rat kidney cells. Neuro-2A cells produce and secrete a PDGF-like growth factor in addition to TGF beta, which can be fully separated from each other by means of reverse-phase HPLC. Using a new, very sensitive technique for detection of TGF beta in growth factor samples based on its additional ability to act as a growth inhibitory factor, it is shown that the PDGF-like growth factor does not contain any detectable TGF beta. Still this neuroblastoma derived PDGF-like growth factor is able to induce anchorage-independent growth of NRK cells, particularly in the additional presence of EGF. It is concluded that under growth factor defined assay conditions TGF beta is not essential for phenotypic transformation of NRK cells.     

Phenotypic transformation of normal rat kidney cells in a growth-factor-defined medium: induction by a neuroblastoma-derived transforming growth factor independently of the EGF receptor

Polypeptide growth factor activity in serum can be destroyed by treatment with dithiothreitol. When such growth-factor-inactivated serum is used as a supplement of culture media instead of regular serum, normal rat kidney (NRK) cells become quiescent unless defined polypeptide growth factors like insulin and epidermal growth factor (EGF) are added. On this basis a growth-factor-defined medium has been developed for NRK cells, which permits cell proliferation as rapidly as in media supplemented with serum, even at low cell densities. Moreover, cells can be serially passaged in this medium. NRK cells can be induced to grow in semisolid media when incubated with transforming growth factors. The growth-factor-defined medium permits soft agar growth experiments of NRK cells, without interference from polypeptide growth factors in serum. Using this assay system we have shown that EGF alone is unable to induce any degree of anchorage-independent growth in NRK cells. However, a recently identified transforming growth factor from mouse neuroblastoma cells which does not compete with EGF for receptor binding is able to induce progressively growing colonies of NRK cells in soft agar, even without additional EGF.     

Type beta transforming growth factor from feline sarcoma virus-transformed rat cells. Isolation and biological properties

We have isolated a strongly mitogenic, type beta transforming growth factor (beta TGF) released by Snyder-Theilen feline sarcoma virus-transformed rat embryo (FeSV-Fre) cells that induces phenotypic transformation of normal NRK cells when they are concomitantly stimulated by analogues of epidermal growth factor (EGF). Molecule filtration chromatography separates beta TGF from an EGF-like TGF (eTGF) which is also present in acid extracts from medium conditioned by FeSV-Fre cells (J. Massagué, (1983) J. Biol. Chem. 258, 13606-13613). Final purification of beta TGF is achieved by reverse phase high pressure liquid chromatography (HPLC) on octadecyl support, molecular filtration HPLC, and nonreducing dodecyl sulfate-polyacrylamide gel electrophoresis steps, yielding a 300,000-fold purified polypeptide with a final recovery of 21%. The purified rat beta TGF consists of two Mr = 11,000-12,000 polypeptide chains disulfide-linked as a Mr = 23,000 dimer. Induction of anchorage-independent proliferation of NRK cells by rat beta TGF depends on the simultaneous presence of eTGF or EGF. In the presence of a saturating (300 pM) concentration of either rat eTGF or mouse EGF, half-maximal anchorage-independent proliferation of NRK cells is obtained with 4-6 pM rat beta TGF. In the presence of a saturating (20 pM) concentration of rat beta TGF, half-maximal anchorage-independent proliferation of NRK cells is obtained with either rat eTGF or mouse EGF at a 50-70 pM concentration. Rat beta TGF is also able to induce DNA synthesis and cell proliferation on growth-arrested NRK, human lung, and Swiss mouse 3T3 fibroblast monolayers, this effect being half-maximal at 2-3 pM beta TGF for NRK cells. These results identify eTGF and beta TGF as the two synergistically acting factors responsible for the transforming action of culture fluids from FeSV-Fre cells.     

Characterization of transforming growth factors produced by the insulin-independent teratoma-derived cell line 1246-3A

The 1246-3A cell line is an insulin-independent variant derived from the adipogenic cell line 1246. Data presented in this paper indicate that the 1246-3A cell line releases in its culture medium two types of transforming growth factors, TGF-alpha- and TGF-beta-like polypeptides, and a growth inhibitor. TGF-alpha like polypeptide eluted from Biogel P60 column into two fractions with an apparent molecular weight of 50 kDa and 13 kDa. These high-molecular-weight TGF-alpha-like factors competed with 125I-EGF for binding to epidermal growth factor (EGF) receptors and were specifically immunoprecipitated by incubation with antirat TGF-alpha antibody, not by incubation with anti-EGF antibody. Both fractions promoted anchorage-independent growth of normal rat kidney NRK cells in the absence of EGF and stimulated DNA synthesis in quiescent Balb/c-3T3 cells in a fashion similar to EGF and synthetic TGF-alpha. In addition to secreting TGF-alpha-like polypeptides, 1246-3A cells produce TGF-beta. This polypeptide, eluted from Biogel P60 chromatography with an apparent molecular weight of 25 kDa, promoted anchorage-independent growth of NRK cells in the presence of EGF and was growth inhibitory for Chinese hamster lung fibroblasts CCL 39 cells. Interestingly, another growth inhibitory activity was detected in Biogel P60 fractions and eluted with an apparent molecular weight of between 9.5-11 kDa. This fraction was different from TGF-beta and TGF-alpha as determined by specific radioreceptor competition assays. TGF-alpha and TGF-beta-like polypeptides could represent autocrine growth stimulators for the insulin-independent 1246-3A cells and act in synergy with insulin-related factor (IRF) for an optimal stimulation of 1246-3A cell proliferation in serum-free medium.     

Analysis of the reduced growth factor dependency of simian virus 40-transformed 3T3 cells.

We have measured in a defined serum-free medium the platelet-derived growth factor (PDGF) and insulin requirements of normal Swiss 3T3 cells, simian virus 40-transformed 3T3 cells, and partial revertants of simian virus 40-transformed 3T3 cells. Swiss 3T3 cells displayed strong requirements for both PDGF and insulin. Both of these requirements were significantly diminished in simian virus 40-transformed 3T3 cells. Analysis of the PDGF and insulin requirements of the revertants indicated that the loss of either of these two growth factor requirements was not necessarily linked to the other; rather, the growth factor requirements were specifically associated with other parameters of transformation. The reacquisition of a PDGF requirement cosegregated with reversion to density-dependent growth inhibition, whereas reacquisition of a normal insulin requirement cosegregated with reversion to a normal growth dependence on calf serum. Anchorage dependence was dissociable from both growth factor requirements. The relationship between the PDGF requirement and density-dependent growth inhibition was further analyzed in normal 3T3 cells by measuring the PDGF requirement at different cell densities. At high cell densities, the requirement for PDGF became significantly greater. We suggest that at least in part the ability of transformed cells to grow to high saturation densities results from their loss of a requirement for PDGF.     

Behavior of transforming growth factors in serum-free media: An improved assay for transforming growth factors

Summary Transforming growth factors (TGFs) are a relatively new category of factors that induce the anchorage-independent growth of non-transformed cells. These factors are usually detected by their ability to induce normal rat kidney (NRK) fibroblasts to grow in soft agar. Until now, this assay has been performed in serum-containing medium (SCM). Unfortunately, the background activity of this assay is variable and dependent on several factors, including passage number of the cells and the serum lot used. Furthermore, the addition of either EGF or TGF-β alone results in the appearance of additional colonies, which decreases the sensitivity of the assay. To circumvent these problems, serum-free media have been developed that support the growth of the NRK cells at low density in both monolayer culture and soft agar. Long-term growth in monolayer cultures occurs in serum-free medium supplemented with laminin, insulin, transferrin, epidermal growth factor (EGF), fibroblast growth factor (FGF) and high density lipoprotein (HDL). Growth in soft agar occurs when TGFs are added to a serum-free medium, AIG medium, that contains insulin, transferrin, FGF and HDL. In contrast to the background activity observed when the assay is performed in SCM, no colonies form in the AIG medium unless TGFs are added and few, if any, colonies form if EGF or TGF-β are added alone. Thus, the AIG medium provides an improved assay for TGFs. In addition, the AIG medium should prove useful for examining other factors, including serum factors, for TGF activity. Editor's Statement This communication describes a modification of the standard assay for transforming growth factors. The techniques employed make use of advantages provided by recent advances in serum-free cell culture to provide a well-defined detection system that is more sensitive than conventional procedures. Experimental approaches described in this article also should be helpful in unraveling differences in cellular behavior encountered under anchorage-dependent vs. anchorage-independent conditions. D. W. Barnes     

Induction of anchorage-independent growth by transforming growth factor-beta linked to anchorage-independent expression of cyclin D1

Transforming growth factor-beta (TGF-beta) was originally identified, characterized, and named on the basis of its ability to induce anchorage-independent growth (phenotypic transformation). This effect has received little attention in recent years, probably because the induction of anchorage-independent growth by TGF-beta has been observed only in a few cell lines, of which NRK fibroblasts are among the best studied. We have previously reported that normal rat kidney cells have lost their normal adhesion requirement for expression of cyclin D1, and we now show that this loss is causal for the induction of anchorage-independent growth by TGF-beta. First, we show that TGF-beta fails to induce anchorage-independent growth in NIH-3T3 cells and human fibroblasts that have retained their adhesion requirement for expression of cyclin D1. Second, we show that TGF-beta complements rather than affects cyclin D-cdk4/6 kinase activity in NRK cells. Third, we show that forced expression of cyclin D1 in suspended 3T3 cells renders them susceptible to transformation by TGF-beta. These results may explain why the induction of anchorage-independent growth by TGF-beta is a rare event and yet also describe a molecular scenario in which the mesenchymal response to TGF-beta could indeed involve the acquisition of an anchorage-independent phenotype.     

Altered response to growth factors or retinoic acid in phenotypic transformation of normal rat kidney cells expressing human c-fos gene.

Anchorage-independent growth of normal rat kidney (NRK) fibroblast in soft agar depends on both transforming growth factor beta (TGF beta) and epidermal growth factor (EGF). To examine whether c-fos protein is involved in phenotypic transformation of NRK cells, we have transfected and isolated several NRK cell lines that carry the human c-fos gene fused to the metallothionein IIA promoter. A transfectant, Nf-1, had constitutive levels of the human c-fos expression. Anchorage-independent growth of Nf-1 was already stimulated by EGF alone, and the colony sizes of Nf-1 were comparable to those of the parental NRK in the presence of both EGF and TGF beta. Anchorage-independent growth of NRK could be observed in the presence of TGF beta or retinoic acid or platelet derived growth factor (PDGF) and EGF. No growth of NRK in soft agar appeared when basic fibroblast growth factor (bFGF) and EGF were present. By contrast, anchorage-independent growth of Nf-1 was surprisingly enhanced by EGF and TGF beta or retinoic acid or PDGF or bFGF. Expression of the human c-fos gene may compensate the signal to phenotypic transformation induced by TGF beta as well as retinoic acid or PDGF or bFGF.     

Phenotypic transformation of normal rat kidney fibroblasts by endothelin-1. Different mode of action from lysophosphatidic acid, bradykinin, and prostaglandin f2alpha

In the present study, we compared the effects of endothelin (ET)-1 on cell proliferation and second messenger induction in normal rat kidney (NRK) fibroblasts, with those of other activators of G-protein-coupled receptors such as prostaglandin (PG)-F2alpha, bradykinin (BK), and lysophosphatidic acid (LPA). LPA is mitogenic by itself, while the other factors require the presence of EGF. In density-arrested NRK cells, ET-1 and LPA induce phenotypic transformation rapidly, with similar kinetics as retinoic acid (RA) and transforming growth factor (TGF)-beta, while BK and PGF2alpha only do so with delayed kinetics. ET-1 and PGF2alpha are strong inducers of anchorage-independent growth, with a similar level of induction as TGFbeta, in contrast to LPA and BK. When investigating the second messenger generation, we found that ET-1 is the strongest activator of arachidonic acid release and phosphatidylinositol diphosphate hydrolysis. Only in the case of ET-1 the cell depolarization is not reversible upon removal of the factor. Similarly, only the ET-1-induced transient enhancement of intracellular calcium concentration is paralleled by both homologous and heterologous desensitization. In conclusion, these data show that ET-1 is a potent inducer of second messengers and phenotypic transformation in NRK cells, with characteristics that clearly differ from those of other activators of G-protein-coupled receptors, most likely as a result of prolonged receptor activation.     

Behavior of transforming growth factors in serum-free media: an improved assay for transforming growth factors

Transforming growth factors (TGFs) are a relatively new category of factors that induce the anchorage-independent growth of non-transformed cells. These factors are usually detected by their ability to induce normal rat kidney (NRK) fibroblasts to grow in soft agar. Until now, this assay has been performed in serum-containing medium (SCM). Unfortunately, the background activity of this assay is variable and dependent on several factors, including passage number of the cells and the serum lot used. Furthermore, the addition of either EGF or TGF-beta alone results in the appearance of additional colonies, which decreases the sensitivity of the assay. To circumvent these problems, serum-free media have been developed that support the growth of the NRK cells at low density in both monolayer culture and soft agar. Long-term growth in monolayer cultures occurs in serum-free medium supplemented with laminin, insulin, transferrin, epidermal growth factor (EGF), fibroblast growth factor (FGF) and high density lipoprotein (HDL). Growth in soft agar occurs when TGFs are added to a serum-free medium, AIG medium, that contains insulin, transferrin, FGF and HDL. In contrast to the background activity observed when the assay is performed in SCM, no colonies form in the AIG medium unless TGFs are added and few, if any, colonies form if EGF or TGF-beta are added alone. Thus, the AIG medium provides an improved assay for TGFs. In addition, the AIG medium should prove useful for examining other factors, including serum factors, for TGF activity.     

Inhibition of normal rat kidney cell growth by transforming growth factor-beta is mediated by collagen

We have investigated the mechanism of inhibition of the serum-free monolayer growth of normal rat kidney (NRK) cells by transforming growth factor-beta (TGF-beta). NRK cells grown on fibronectin-coated dishes exhibited a biphasic response to TGF-beta. Monolayer growth was slightly stimulated by subpicomolar concentrations, while picomolar concentrations of TGF-beta inhibited NRK cell growth in the presence or absence of epidermal growth factor. NRK cells exhibited a similar biphasic growth response to exogenous type I collagen. TGF-beta induced a 3-5-fold increase in the deposition of type I collagen-like proteins into the extracellular matrix of NRK cells during serum-free growth. Type I collagen-like proteins were identified by their sensitivity to degradation by purified bacterial collagenase and by Western blot analysis. The TGF-beta dose-response curves for induction of extracellular matrix-localized collagen and inhibition of NRK cell growth were similar. Finally, the inclusion of a purified bacterial collagenase, which did not degrade TGF-beta or TGF-beta receptors, or alter control NRK growth, prevented exogenous collagen or TGF-beta from inhibiting the serum-free growth of NRK cells. Our results demonstrate that an increase in collagen secretion plays an important role in the inhibition of the growth of NRK cells by TGF-beta.     

A cell cycle and mutational analysis of anchorage-independent growth: cell adhesion and TGF-beta 1 control G1/S transit specifically

We have examined cell cycle control of anchorage-independent growth in nontransformed fibroblasts. In previous studies using G0-synchronized NRK and NIH-3T3 cells, we showed that anchorage-independent growth is regulated by an attachment-dependent transition at G1/S that resembles the START control point in the cell cycle of Saccharomyces cerevisiae. In the studies reported here, we have synchronized NRK and NIH-3T3 fibroblasts immediately after this attachment-dependent transition to determine if other portions of the fibroblast cell cycle are similarly regulated by adhesion. Our results show that S-, G2-, and M-phase progression proceed in the absence of attachment. Thus, we conclude that the adhesion requirement for proliferation of these cells can be explained in terms of the single START-like transition. In related studies, we show that TGF-beta 1 overrides the attachment-dependent transition in NRK and AKR-2B fibroblasts (lines in which TGF-beta 1 induces anchorage-independent growth), but not in NIH-3T3 or Balb/c 3T3 fibroblasts (lines in which TGF-beta 1 fails to induce anchorage- independent growth). These results show that (a) adhesion and TGF-beta 1 can have similar effects in stimulating cell cycle progression from G1 to S and (b) the differential effects of TGF-beta 1 on anchorage- independent growth of various fibroblast lines are directly reflected in the differential effects of the growth factor at G1/S. Finally, we have randomly mutagenized NRK fibroblasts to generate mutant lines that have lost their attachment/TGF-beta 1 requirement for G1/S transit while retaining their normal mitogen requirements for proliferation. These clones, which readily proliferate in mitogen-supplemented soft agar, appear non-transformed in monolayer: they are well spread, nonrefractile, and contact inhibited. The existence of this new fibroblast phenotype demonstrates (a) that the growth factor and adhesion/TGF-beta 1 requirements for cell cycle progression are genetically separable, (b) that the two major control points in the fibroblast cell cycle (G0/G1 and G1/S) are regulated by distinct extracellular signals, and (c) that the genes regulating anchorage- independent growth need not be involved in regulating contact inhibition, focus formation, or growth factor dependence.     

Transforming growth factor-beta enhances the extent of intercellular communication between normal rat kidney cells

Normal rat kidney (NRK) cells cultured in the presence of epidermal growth factor are contact-inhibited at confluent densities. In the additional presence of transforming growth factor (TGF)-beta, however, cells undergo phenotypic transformation which is accompanied by a loss of contact inhibition. In this study, we show by means of the fluorescence photobleaching recovery technique and a scrape-loading dye transfer technique that quiescent confluent cultures of NRK cells do not show extensive gap junction-mediated intercellular communication. Cells contact-inhibited in the presence of epidermal growth factor also show only limited intercellular communication, although with an enhanced permeability coefficient. Cells phenotypically transformed upon addition of TGF beta, however, show extensive intercellular communication, with a similarly enhanced permeability coefficient. This enhanced intercellular communication induced by TGF beta is paralleled by an increase in intracellular pH. It is concluded that in contrast to what has been observed during tumorigenic transformation, phenotypic transformation of NRK cells induced by TGF beta results in an enhancement of the extent of gap junction-mediated intercellular communication.     

Restoration of anchorage regulation in transformed cells by retinoic acid (RA) is independent of the presence of cytoplasmic RA-binding proteins

In an attempt to analyse the cause-effect relationship between anchorage-independent growth (a property which correlates best with in vivo tumorigenicity) and a set of other common transformation-related properties, the effect of retinoic acid (RA) treatment on six unrelated transformed cell lines (including DNA tumor virus, retrovirus, and spontaneously transformed cells) were studied. The data show that the changes in morphology and cellular orientation in culture, loss of cell surface fibronectin, disruption of actin microfilaments, increased hexose uptake, loss of density-dependent growth, and decreased binding of EGF, properties which are often associated with oncogenic transformation of cells, are dissociable from one another and from anchorage-independent growth. RA appears to interfere with anchorage-independent growth of all the retrovirus and spontaneously transformed cell lines (responsive cells) that we examined; however, such treatment failed to inhibit anchorage-independent growth in both of the DNA tumor virus-transformed cell lines (non-responsive cells) that we used in the present study. The presence of RA-binding proteins in both responsive and non-responsive cells suggests that the mechanism of RA action for the inhibition of anchorage-independent growth in transformed cells may be independent of the presence of such cytoplasmic proteins. Finally, the present study clearly indicates that the use of RA treatment, like partial transformation mutants of oncogenic viruses, can be a novel approach in analysing the general mechanism by which transformed cells grow without anchorage.     

Platelet-derived growth factor or basic fibroblast growth factor induce anchorage-independent growth of human fibroblasts

Anchorage-independent growth, i.e., growth in semi-solid medium is considered a marker of cellular transformation of fibroblast cells. Diploid human fibroblasts ordinarily do not exhibit such growth but can grow transiently when medium contains high concentrations of fetal bovine serum. This suggests that some growth factor(s) in serum is responsible for anchorage-independent growth. Much work has been done to characterize the peptide growth factor requirements of various rodent fibroblast cells for anchorage-independent growth; however, the requirements of human fibroblasts are not known. To determine the peptide growth factor requirements of human fibroblasts for anchorage-independent growth, we used medium containing serum that had had its peptide growth factors inactivated. We found that either platelet-derived growth factor (PDGF) or the basic form of fibroblast growth factor (bFGF) induced anchorage-independent growth. Epidermal growth factor (EGF) did not enhance the growth induced by PDGF, or did so only slightly. Transforming growth factor beta (TGF-beta) decreased the growth induced by PDGF. EGF combined with TGF-beta induced colony formation in semi-solid medium at concentrations at which neither growth factor by itself was effective, but the combination was much less effective in stimulating anchorage-independent growth than PDGF or bFGF. This work showed that PDGF, or bFGF, or EGF combined with TGF-beta can stimulate anchorage-independent growth of nontransformed human fibroblasts. The results support the idea that cellular transformation may reduce or eliminate the need for exogenous PDGF or bFGF.     

Transforming growth factor activity of bovine brain-derived growth factor

Bovine brain-derived growth factor (BDGF), whose biochemical properties resemble those of endothelial cell growth factor (ECGF) and brain-derived acidic fibroblast growth factor (acidic FGF), is able to promote colony formation of normal rat kidney fibroblasts (NRK cells) in soft agar. As in the case of transforming growth factor beta (TGF beta), EGF potentiates the anchorage-independent growth promoting activity of BDGF. In the presence of EGF (5 ng/ml), the optimal concentration of BDGF for stimulation of anchorage-independent of NRK cells is approximately 0.5 ng/ml. At higher concentrations, BDGF becomes inhibitory. The anchorage-independent cell growth promoting activity of BDGF differs from that of TGF beta in acid and reducing agent stability.     

On the autocrine growth regulation of Morris hepatoma cells

Chemically induced, transplantable Morris hepatoma 7777 cells (MH) were examined for their anchorage-dependent and anchorage-independent growth properties. MH cells were found to grow on solid surface in a density-dependent manner, with respect to serum factors and gelatinization. The correlation between anchorage independent growth of MH cells and agar or serum concentrations in the culture medium was described. The ability of MH cells to stimulation of soft agar colony formation of NRK-49F indicator cells in coculture assay was presented. Autocrine control of proliferation of MH cells by TGFs-like factor(s) was suggested.