Extracellular ATP Induces Anchorage-independent Expression of Cyclin A and Rescues the Transformed Phenotype of a Ras-resistant Mutant Cell Line*

(Received for publication, August 26, 1996, and in revised form, October 17, 1996)

Jaw-Ji Yang and Robert S. Krauss Dagger

From the Department of Biochemistry, Mount Sinai School of Medicine, New York, New York 10029

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

Anchorage-independent growth is characteristic of neoplastic cells, but the signal transduction pathways that mediate this phenotype are poorly understood. Several important cell cycle events are dependent on cell-substratum adhesion in non-transformed cells, including activation of G1 cyclin-dependent kinases and expression of cyclin A; the adhesion requirement of these events is abrogated in Ras-transformed cells. The ER-1-2 mutant rat fibroblast cell line is: 1) resistant to Ras-mediated, anchorage-independent growth; 2) defective in Ras-mediated, adhesion-independent expression of cyclin A, but not adhesion-independent activation of cyclin-dependent kinases; and 3) rescued for Ras-induced, anchorage-independent growth by ectopic expression of cyclin A. We report here that extracellular ATP induces adhesion-independent expression of cyclin A and rescues growth in soft agar by ER-1-2 cells that express Ras. ADP, AMP and the non-hydrolyzable analog adenosine 5'-(beta ,gamma -iminodiphosphate) are also effective, but adenosine is not. Adenine nucleotide-induced growth in soft agar is inhibited by reactive blue 2, an antagonist of some P2 purinoceptors. ATP does not induce adhesion-independent expression of cyclin A in ER-1-2 or control rat fibroblasts that do not express Ras, indicating a requirement for additional Ras-regulated signals for expression of this gene; one such signal may lead to phosphorylation of the retinoblastoma protein, pRB, and related proteins. These results suggest that extracellular ATP could play a role in the multistage carcinogenic process in vivo.


INTRODUCTION

The ability of neoplastically transformed cells to proliferate in the absence of cell-substratum adhesion (i.e. anchorage-independent growth) is the best in vitro correlate of tumorigenicity (1). It is reasonable to hypothesize, therefore, that the molecular mechanisms that underlie anchorage-independent growth are related to the mechanisms that mediate some of the aggressive growth properties of malignant tumors. Despite the widespread use of colony formation in soft agar as an assay for the transformed phenotype, the signal transduction pathways that oncogenes use to drive this aberrant form of cell proliferation are poorly understood. We have developed a system that allows analysis of oncogene-induced, anchorage-independent growth independently from several other transformation-associated phenotypes (2). The Rat 6 fibroblast-derived, somatic cell mutant line ER-1-2 responds to expression of the Ras oncoprotein with alterations in cell morphology and gene expression that are nearly indistinguishable from those of a control cell line, PKC3-F4 (2, 3). Unlike PKC3-F4 cells, however, ER-1-2 cells fail to form colonies in soft agar in response to Ras (2). ER-1-2 cells are also resistant to anchorage-independent growth induced by v-Src and v-Raf, and this phenotype is dominant in somatic cell hybridizations.

We and others have previously demonstrated that several important cell cycle events are dependent on cell-substratum adhesion of fibroblast cell lines, including activation of G1 cyclin-dependent kinases (Cdks)1 (as measured by pRB phosphorylation, and cyclin E- and A-dependent kinase activities) and expression of the cyclin A gene (4-7). PKC3-F4 and NIH 3T3 cells that express oncogenic Ras proliferate in non-adherent cultures, and all of these cell cycle events occur in the absence of adhesion in the Ras-transformed derivatives (5). In contrast, ER-1-2 cells that express Ras (ER-1-2/ras cells) possess G1 Cdk activities when cultured without adhesion, but remain almost fully adhesion-dependent for expression of cyclin A (5). Furthermore, ectopic expression of cyclin A is sufficient to rescue anchorage-independent growth of ER-1-2/ras cells, but does not induce anchorage-independent growth of PKC3-F4 or ER-1-2 cells, presumably because these cells still lack G1 Cdk activity in the absence of adhesion (5). These data therefore indicate that: 1) oncogenic Ras can supplant the adhesion requirement of cellular functions that are necessary for cell cycle progression, 2) the adhesion dependence of G1 Cdk activity can be dissociated from the adhesion dependence of cyclin A expression, and 3) the ability of Ras to direct expression of cyclin A in the absence of cell-substratum adhesion may be a critical, but insufficient, aspect of its transforming properties.

Taken together, the results of several studies suggest that cell-substratum adhesion is likely to regulate multiple signaling pathways that lead independently to activation of G1 Cdks and expression of cyclin A (4, 5, 7). The observation that, in the ER-1-2 cell line, Ras is able to overcome the adhesion requirement of G1 Cdk activation, but not the adhesion requirement of cyclin A expression, suggests that Ras also signals via multiple pathways to achieve anchorage-independent growth. This is consistent with numerous recent reports, which indicate that Ras has multiple direct effectors and relies on multiple pathways to achieve cell transformation (8-10). The signal transduction pathways utilized by Ras to overcome the adhesion requirement of Cdk activation and expression of cyclin A are not known. ER-1-2/ras cells, which are apparently defective only in anchorage-independent expression of cyclin A, display constitutively active mitogen-activated protein kinase (MAPK), and the transformed phenotype of these cells is not rescued by ectopic expression of activated alleles of MAPK kinase, Rac1 or RhoA.2 Thus, the pathways controlled by these established mediators of Ras's transforming potential (11-14) may not directly regulate, or be sufficient for, anchorage-independent expression of cyclin A.

Extracellular adenine nucleotides have received considerable attention as signal transducing ligands for a growing family of plasma membrane receptors, termed P2 purinoceptors (for review, see Refs. 15 and 16). Two different types of P2 receptors have been described: P2X receptors, which are structurally distinctive, ligand-gated ion channels; and P2Y receptors, which are G protein-coupled receptors with seven transmembrane domains. At least seven different P2X receptors and seven different P2Y receptors have been molecularly cloned, and additional receptors have been characterized pharmacologically (see Refs. 16-18 and references therein). Extracellular ATP, operating via P2 purinoceptors, can elicit an extremely wide range of biological effects in different systems (15). Of particular interest to the studies reported here are the observations of Heppel and colleagues that extracellular ATP can act as a mitogen or co-mitogen for a number of different fibroblast cell lines (19-21). We have recently described a low molecular weight, hydrophilic, heat-and protease-resistant, secreted factor (designated <UNL>t</UNL>ransformation-<UNL>r</UNL>estoring <UNL>f</UNL>actor, TRF) that specifically rescues anchorage-independent growth of ER-1-2/ras cells (22). Interestingly, TRF can be destroyed by ultraviolet light (UV) of 260 nm wavelength, indicating the presence of one or more critical UV-labile chemical bonds.2 Based on its chemical properties, the hypothesis that TRF might be an adenine nucleotide was tested. We report here that extracellular ATP rescued anchorage-independent growth of ER-1-2/ras cells. Furthermore, ATP induced expression of cyclin A in non-adherent cultures of ER-1-2/ras cells. Contrary to our original hypothesis, however, TRF does not appear to be an adenine nucleotide and exerted its effects on anchorage-independent growth via a mechanism distinct from that used by ATP.


EXPERIMENTAL PROCEDURES

Materials

ATP, ADP, AMP, GTP, UTP, AMP-PNP, adenosine, and the calcium ionophore A23187 were all from Boehringer Mannheim. alpha ,beta -Methylene-ATP (alpha ,beta -Me-ATP), beta ,gamma -methylene-ATP (beta ,gamma -Me-ATP), P1,P4-di(adenosine-5') tetraphosphate (AppppA), 12-O-tetradecanoylphorbol-13-acetate, thapsigargin, reactive blue 2, and 8-bromo-cAMP were all from Sigma. 2-Methylthio-ATP (2-Me-S-ATP) and pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS) were from Research Biochemicals International.

Cell Culture

All cell lines were routinely maintained in Dulbecco's modified Eagle's medium (Life Technologies, Inc.) plus 10% calf serum as described previously (2). Soft agar assays were performed as described in Ref. 22. Adenine nucleotides and other chemical compounds were added to the soft agar medium at the time the cells were initially inoculated, and with each subsequent feeding. When potential chemical inhibitors of ATP- or TRF-induced anchorage-independent growth were tested, cells were pretreated with the inhibitor for 1 h while growing on tissue culture plates and then inoculated into agar medium with ATP or TRF and inhibitor. For subsequent feedings, the inhibitors were added to one-half the standard feeding volume and the medium was then overlaid on the agar cultures. After a 1-h incubation at 37 °C, an additional 0.5 volume containing ATP or TRF was added and the cultures were placed back in the incubator. To recover cells cultured under non-adherent conditions, preparative methylcellulose cultures were used in place of soft agar cultures (5). Briefly, 1 × 105 cells were inoculated into 10 ml of Dulbecco's modified Eagle's medium containing 5% calf serum and 1.3% methylcellulose, in a 50-ml conical tube. The tubes were then placed in a water-jacketed CO2 incubator at 37 °C. Three days later, the medium was diluted with 40 ml of ice-cold phosphate-buffered saline (to solubilize the methylcellulose), and the cells were recovered by gentle centrifugation. Recovery of cells by this method was nearly quantitative, and cell viability was >98%, as determined by trypan blue dye exclusion assays. The growth properties in soft agar and methylcellulose of the cell lines used in these studies are nearly identical (5).

Protein and RNA Analyses

Immunoblotting analyses were performed as described (5). Nitrocellulose membranes were probed with antibodies against cyclin A (courtesy of R. Assoian, University of Miami; and M. Pagano, New York University), cyclin D (Upstate Biotechnology Inc.), cyclin E (courtesy of J. Roberts, Fred Hutchinson Cancer Center) or pRB (PharMingen). After hybridization with the primary antibody, the membrane was reprobed with horseradish peroxidase-conjugated secondary antibody and specific protein bands detected with an enhanced chemiluminescence (ECL) system (Amersham Corp.). Northern blot analysis of total cellular RNA extracted with Trizol (Life Technologies, Inc.) was performed as described (2).

Partial Purification of TRF

TRF was partially purified by fractionating serum-free conditioned medium derived from Rat 6 fibroblasts by size exclusion chromatography on a Bio-Gel P2 column (Bio-Rad) as described previously (22). Active fractions were pooled, lyophilized, dissolved in water, and sterile-filtered prior to use.


RESULTS

Rescue of Anchorage-independent Growth of ER-1-2/ras Cells By ATP and Structural Analogs

Because we had previously characterized TRF as a low molecular weight, non-protein, non-lipid secreted factor (22) that is inactivated by UV light,2 we have tested various cell-derived factors with similar chemical properties for their ability to rescue anchorage-independent growth of ER-1-2/ras cells. Table I and Fig. 1 show that inclusion of 50 µM ATP in the agar medium induced colony formation of ER-1-2/ras cells and two independent subclones of ER-1-2/ras (designated ERRC1 and ERRC6), but did not induce colony formation in the non-Ras-expressing PKC3-F4 or ER-1-2 cell lines. Furthermore, ATP did not enhance colony formation by the fully transformed PKC3-F4/ras cells (Table I and Fig. 1), nor did it enhance the growth of ER-1-2/ras cells cultured on plastic dishes (data not shown). Thus, similar to TRF and ectopic expression of cyclin A (5, 22), extracellular ATP specifically rescued anchorage-independent growth of ER-1-2/ras cells. We next tested the ability of ATP and other adenine nucleotides to rescue growth in soft agar of ER-1-2/ras cells over the dose range 0.01-100 µM (Fig. 2A). ATP, ADP, and AMP were all equipotent, with an EC50 of <10 µM, and colony formation was observed at doses as low as 1 µM. The non-hydrolyzable ATP analog, AMP-PNP, was as effective as ATP itself, indicating that hydrolysis of ATP was not necessary for its effects in this system (Fig. 2A). In contrast, adenosine was inactive at concentrations up to 100 µM (Fig. 2A).

Table I.

Rescue of growth in soft agar of ER-1-2/ras cells by extracellular ATP


Cell line Growth in soft agar (colonies/104 cells)a
 - ATP + ATP

PKC3-F4 0 0
PKC3-F4/ras 2442 2432
ER-1-2 0 0
ER-1-2/ras 0 499
ERRC1 0 474
ERRC6 0 691

a  A total of 10,000 cells of each cell line were seeded into 0.3% agar, in the presence or absence of ATP (50 µM). Macroscopic colonies were scored after 2 weeks of growth. Values represent averages of duplicate determinations that differed by less than 5%. The experiment was repeated at least three times for each cell line; representative data are shown.


Fig. 1. Soft agar colony formation by various cell lines in the presence or absence of ATP. Cells were cultured as described under "Experimental Procedures" and the legend to Table I. See Table I for quantitation of results. Magnification, ×40.
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Fig. 2. Pharmacological characterization of the effects of ATP on soft agar colony formation of ER-1-2/ras cells. A, dose-response curves for ATP, ADP, AMP, AMP-PNP, and adenosine; B, dose-response curves for reactive blue 2-mediated inhibition of colony formation by ATP, ADP, AMP (each used at 50 µM), and partially purified TRF; C, dose-response curves for ATP, alpha ,beta -Me-ATP, beta ,gamma -Me-ATP, and 2-Me-S-ATP. Each data point represents the average of duplicate determinations that differed by less than 5%. For A and C, the data points represent 1, 5, 10, 25, 50, and 100 µM concentrations for each analog; the 0.00, 0.01, and 0.1 µM concentrations for each analog yielded no colonies, and the data points are not shown on the graph. The experiments shown in A and B were performed three times, and the experiment shown in C performed twice, with very similar results; representative data are shown.
[View Larger Version of this Image (14K GIF file)]


To begin to examine whether adenine nucleotides might be acting via a P2 purinoceptor, we tested the effects of inhibitors of these receptors on soft agar colony formation by ER-1-2/ras cells mediated by adenine nucleotides (50 µM) or partially purified TRF. There is currently a lack of highly specific antagonists for the various different P2 purinoceptors. However, reactive blue 2 and PPADS are considered to be relatively specific antagonists for P2Y and P2X receptors, respectively (16). Fig. 2B demonstrates that reactive blue 2 inhibited adenine nucleotide-induced colony formation with an IC50 of ~20 µM. In contrast, TRF-mediated colony formation was not affected by reactive blue 2 at concentrations up to 100 µM, demonstrating that the effect of reactive blue 2 on adenine nucleotide-mediated colony formation was specific and not due to toxicity to the cells (Fig. 2B). These data also indicate that TRF and adenine nucleotides exerted their effects on ER-1-2/ras cells via distinct mechanisms. PPADS did not inhibit colony formation induced either by ATP or by TRF (data not shown).

We next tested various ATP analogs and other nucleotides for their ability to stimulate anchorage-independent growth of ER-1-2/ras cells over the dose range 0.01-100 µM (Fig. 2C). beta ,gamma -Me-ATP was as effective as ATP at higher doses, but was reproducibly less efficacious at concentrations <20 µM. In contrast, alpha ,beta -Me-ATP, 2-Me-S-ATP, UTP, GTP, and AppppA were all inactive in this assay (Fig. 2C and data not shown). Because alpha ,beta -Me-ATP, 2-Me-S-ATP, and UTP are more potent agonists than ATP for certain purinoceptors (16), and the assay used here involved chronic exposures, it was possible that these compounds were desensitizing a signaling system responsible for inducing anchorage-independent growth and that their inactivity was therefore artifactual. To address this point, the ability of alpha ,beta -Me-ATP, 2-Me-S-ATP, or UTP to inhibit colony formation of ER-1-2/ras cells by 50 µM ATP was tested over the dose range 1-100 µM. None of these three compounds were able to inhibit ATP-mediated colony formation at any dose tested, ruling out a desensitization role for these analogs (data not shown). Finally, we tested several second messenger mimetics in this system: the phorbol ester 12-O-tetradecanoylphorbol-13-acetate, thapsigargin, arachidonic acid, and the calcium ionophore A23187 were all inactive in stimulating anchorage-independent growth of ER-1-2/ras cells (data not shown). 8-Bromo-cAMP also did not stimulate growth of ER-1-2/ras cells and, in fact, potently inhibited anchorage-independent growth of the fully transformed PKC3-F4/ras cells (data not shown).

Extracellular ATP Induces Anchorage-independent Expression of Cyclin A

The ER-1-2 cell line is defective in Ras-mediated, anchorage-independent expression of cyclin A, and ectopic expression of cyclin A rescues colony formation of ER-1-2/ras cells in soft agar (5). It was of interest, therefore, to test whether ATP induced anchorage-independent expression of the endogenous cyclin A gene in ER-1-2/ras cells. Because it is not possible to recover viable, non-adherent cells from soft agar cultures, we utilized a methylcellulose culture system that allows for nearly quantitative recovery of intact cells cultured under non-adherent conditions (5). It has been demonstrated previously that the growth properties in soft agar and methylcellulose of the cell lines used in these studies are nearly identical (5). Furthermore, ATP induced colony formation of ER-1-2/ras cells in methylcellulose cultures at a similar frequency as in soft agar cultures, and this colony formation was inhibited by reactive blue 2 (data not shown). As shown in Fig. 3A, ER-1-2/ras cells expressed only trace levels of cyclin A protein in methylcellulose cultures that were not supplemented with ATP, but addition of 50 µM ATP induced expression of cyclin A in such cultures. This response was not an indirect effect due simply to ATP driving the ER-1-2/ras cells through the cell cycle because partially purified TRF did not induce cyclin A in these cells (Fig. 3A), despite the fact that it rescued colony formation to a similar extent as ATP (Ref. 22 and see Fig. 4). The specificity of this response was further underscored by the observation that ATP did not alter the levels of cyclins D1 and E in methylcellulose cultures of ER-1-2/ras cells (Fig. 3A). Northern blot analyses demonstrated that the induction of cyclin A by ATP occurred at the RNA level (Fig. 3B). To examine the time course of cyclin A induction by ATP, ER-1-2/ras cells were inoculated into methylcellulose-containing medium and incubated for 24 h to allow some decay of adhesion-mediated cyclin A production. ATP was then added to the cultures and cyclin A protein levels analyzed at various time points thereafter. As shown in Fig. 3C, cyclin A levels continued to decrease over the next 6 h in both ATP-treated and untreated cultures. There was only a small effect on cyclin A expression between 3 and 12 h after exposure to ATP, but by 24 h post-treatment cyclin A was fully induced.


Fig. 3. Effects of ATP on anchorage-independent expression of various cell cycle proteins in ER-1-2/ras, PKC3-F4, and ER-1-2 cell lines. Cells were grown on tissue culture plates (+ adhesion) or in preparative methylcellulose cultures (- adhesion), in the presence (+) or absence (-) of ATP or partially purified TRF. Cells were then harvested, lysed, and 50 µg of total cellular protein analyzed by Western blotting and probing with specific antibodies (A, C, D, and E), or 10 µg of total cellular RNA analyzed by Northern blotting and hybridization with a cyclin A cDNA probe (B). A, expression of cyclin A, D1, and E proteins in ER-1-2/ras cells. B, expression of cyclin A mRNA in ER-1-2/ras cells. The two bands represent the 3.0- and 1.8-kilobase cyclin A mRNAs. The ethidium bromide-stained gel, featuring the 28 and 18 S rRNA bands, is shown as a loading control. C, time course of ATP-induced, anchorage-independent expression of cyclin A protein in ER-1-2/ras cells. D, expression of cyclin A protein in PKC3-F4 and ER-1-2 cells. The lower molecular mass protein band present in the adherent ER-1-2 cell sample is an apparent degradation product of cyclin A. E, phosphorylation status of pRB. The hyperphosphorylated (ppRB) and hypophosphorylated (pRB) forms are distinguished by their mobilities and are indicated by arrows.
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Fig. 4. Additive effects of ATP and TRF on soft agar colony formation by ER-1-2/ras cells. ER-1-2/ras cells were inoculated into soft agar medium containing either ATP (50 µM), a maximally effective dose of partially purified TRF, or both. Values represent averages of triplicate determinations ± one standard deviation. The experiment was performed twice; representative data are shown.
[View Larger Version of this Image (42K GIF file)]


We next asked whether ATP could induce cyclin A expression in the PKC3-F4 and ER-1-2 cell lines, which were not induced to grow in soft agar by this compound. As seen in Fig. 3D, expression of cyclin A was completely adhesion-dependent in these two cell lines, and ATP did not lead to expression of cyclin A in non-adherent, methylcellulose cultures of these cells. Thus, additional Ras-mediated signals were required for anchorage-independent expression of cyclin A. A role for the E2F transcription factor has been implicated in the induction of the cyclin A gene near the G1/S phase border (23). Because E2F activity is strongly influenced by the phosphorylation status of pRB family members (24), and pRB phosphorylation is an adhesion-dependent event (5, 7), we investigated the effects of ATP on pRB phosphorylation in non-adherent cultures of PKC3-F4, ER-1-2, and ER-1-2/ras cells. Similar to our previous observations, pRB was hypophosphorylated in extracts prepared from non-adherent cultures of PKC3-F4 and ER-1-2 cells (Fig. 3E). Consistent with its inability to induce cyclin A or soft agar colony formation in PKC3-F4 and ER-1-2 cells, addition of ATP to these cells in the absence of adhesion had no effect on the phosphorylation status of pRB. It is possible, therefore, that one of the additional Ras-mediated events that is necessary for anchorage-independent expression of cyclin A is phosphorylation of pRB family members and, by implication, resultant alterations in E2F activity. As expected, pRB was hyperphosphorylated in ER-1-2/ras cells with or without treatment with ATP (Fig. 3E).

TRF did not induce anchorage-independent expression of cyclin A (Fig. 3A), yet it rescued colony formation in soft agar of ER-1-2/ras cells (22). These data suggest that TRF exerted its effects via a mechanism distinct from that used by ATP, which did induce cyclin A. If this were true, it would be predicted that the effects of TRF and ATP would be at least additive. To test this hypothesis, 50 µM ATP (a saturating dose; see Fig. 2A) was mixed with a maximally effective dose of partially purified TRF (22), and the number of soft agar colonies formed by ER-1-2/ras cells treated with the mixture was compared to the number formed with each agent alone. As can be seen in Fig. 4, the mixture of ATP and TRF had a slightly more than additive effect when compared to either compound alone.


DISCUSSION

Anchorage-independent growth is the best in vitro correlate of tumorigenicity (1); identification of the oncoprotein-driven signaling pathways that mediate this aberrant form of cell proliferation is therefore necessary for molecular elucidation of the transformed phenotype. Recent studies indicate that several biochemical events that are necessary for cell cycle progression are dependent on cell-substratum adhesion in non-transformed cells. These events include activation of G1 cyclin-Cdk complexes (as measured by pRB phosphorylation, and cyclin E- and A-dependent kinase activities) and expression of the cyclin A gene (5-7). NIH 3T3 and Rat 6-derived fibroblast cell lines that are transformed by Ras display both G1 Cdk activities and expression of cyclin A even when cultured under non-adherent conditions (5). The functional relevance of these observations is demonstrated in the ER-1-2 somatic cell mutant line, which is resistant to Ras-induced, anchorage-independent growth (2). ER-1-2/ras cells exhibit G1 Cdk activities in non-adherent cultures, but are defective for expression of cyclin A under such conditions (5). Ectopic expression of cyclin A is sufficient to rescue growth in soft agar of ER-1-2/ras cells, but is not sufficient to induce anchorage-independent growth of Rat 6-derived lines that do not express Ras. Thus, Ras-mediated events other than anchorage-independent expression of cyclin A are also required for growth in soft agar; one such event is likely to be loss of the adhesion requirement for G1 Cdk activity.

With such functionally relevant end points as anchorage-independent expression of cyclin A now identified, it should be possible to dissect the signaling pathways utilized by Ras to drive anchorage-independent growth. In particular, it should be possible to exploit the ER-1-2/ras cell line toward this end. Constitutively activated forms of components of these pathways would be predicted to rescue growth in soft agar of these cells in the same fashion that ectopic expression of cyclin A did, provided that they function downstream of the defective signaling point in these cells. We have recently observed that ER-1-2/ras cells display constitutively active MAPK and, further, that the transformed phenotype of these cells is not rescued by ectopic expression of activated alleles of MAPK kinase, Rac1 or RhoA,2 each of which is required for transformation by Ras (11-14). Thus, it is possible that the pathways controlled by these proteins may not directly regulate, or be sufficient for, anchorage-independent expression of cyclin A. Alternatively, the defective signaling point in ER-1-2/ras cells might reside between one of these proteins and the cyclin A gene. We report here that an extracellular signaling agent, ATP, induced anchorage-independent expression of cyclin A and rescued growth in soft agar in ER-1-2/ras cells. These data argue that a pathway that leads to induction of the cyclin A gene in the absence of the normal adhesion requirement is functional in these cells and can be activated by extracellular adenine nucleotides. The observations that: 1) an antagonist of P2Y purinoceptors (reactive blue 2) blocked the effects of adenine nucleotides on agar growth, and 2) a non-hydrolyzable ATP analog (AMP-PNP) was fully efficacious, suggest that the adenine nucleotides might have exerted their effects via activation of a purinoceptor. If this is the case, we are not aware of any cloned or characterized receptor that displays a similar pharmacological profile (16).

Expression of the cyclin A gene is dramatically up-regulated in non-transformed cells at the G1/S border, and cyclin A is required for the G1/S transition and progression through both S and G2 phases (for review, see Refs. 25 and 26). In fibroblasts, expression of cyclin A requires signals from both growth factors and cell-substratum adhesion, and occurs as late as 18 h after adherent, quiescent cells are treated with growth factors (25, 26). The cyclin A gene promoter must therefore integrate information from multiple signaling pathways that has accrued over a considerable period of time. It is striking that cyclin A was induced in an adhesion-independent manner in ER-1-2/ras cells by treatment with a soluble, extracellular signaling factor, ATP. Perhaps ATP- and integrin-mediated signaling pathways overlap in Rat 6 cells. Signals provided by ATP treatment were not sufficient to induce cyclin A, however, since PKC3-F4 and ER-1-2 cells that did not express Ras did not respond, nor were they stimulated to grow in soft agar. Thus, additional Ras-mediated events were necessary for anchorage-independent expression of cyclin A, which, as described above, was itself insufficient to drive proliferation of suspended cells. Because non-adherent PKC3-F4 and ER-1-2 cells displayed only hypophosphorylated pRB even when treated with ATP, and E2F activity has been implicated in cyclin A gene induction (23), one likely possibility for an additional required event is phosphorylation of pRB family members and concomitant alterations in E2F activity. Taken together, it appears that the putative dominant mutation in ER-1-2 cells acts very specifically to block a Ras-regulated signaling pathway that, in cooperation with other Ras-regulated events, leads to anchorage-independent expression of cyclin A and therefore to growth in soft agar. We propose that signals provided by ATP, possibly via activation of a purinoceptor, feed into this pathway at a point downstream of the point of blockade in ER-1-2 cells. The requirement for multiple Ras-regulated signaling and cell cycle events for anchorage-independent growth is consistent with the notion that anchorage-independent growth is the most stringent in vitro criterion of transformation and has a very high correlation with tumorigenicity (1).

We originally tested ATP for its effects on ER-1-2/ras cells because the chemical properties of TRF might be consistent with those of a nucleotide (22). The effects of TRF were not, however, inhibited by reactive blue 2, nor did TRF induce cyclin A expression, despite its ability to rescue growth in soft agar of these cells (22). It is concluded that TRF is very likely not an adenine nucleotide. The mechanism of action of TRF remains unknown; the fact that it can drive proliferation of cells that produce only trace levels of cyclin A underscores the complexity of the perverse growth properties of oncogene-transformed cells.

Further analysis of ATP-mediated signaling in ER-1-2/ras cells could provide insight into the signaling pathways utilized by Ras to induce anchorage-independent growth in wild-type cells. The observations presented here may have further implications, as well. The ability of extracellular adenine nucleotides to influence a cell cycle event that is strongly linked to the transformed phenotype suggests that these compounds could play a role in multistage carcinogenesis in vivo. For example, early in the carcinogenic process, it is possible that cells could acquire the ability to carry out the activation of G1 Cdks without adhesion signals, but not yet the ability to express cyclin A under such conditions. Exposure to adenine nucleotides might serve as a tumor promotion-like stimulus to such cells.


FOOTNOTES

*   This work was supported in part by National Institutes of Health CA59474, the Leukemia Research Foundation, and a Sinsheimer Scholar's Award (to R. S. K.) The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    Career scientist of the Irma T. Hirschl Trust. To whom correspondence should be addressed: Dept. of Biochemistry, Box 1020, Mount Sinai School of Medicine, New York, NY 10029. Tel.: 212-241-2177; Fax: 212-996-7214.
1    The abbreviations used are: Cdk, cyclin-dependent kinase; MAPK, mitogen-activated protein kinase; TRF, transformation-restoring factor; 2-Me-S-ATP, 2-methylthio-ATP; PPADS, pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid; alpha ,beta -Me-ATP, alpha ,beta -methylene-ATP; beta ,gamma -Me-ATP, beta ,gamma -methylene-ATP; AppppA, P1,P4-di(adenosine-5') tetraphosphate; AMP-PNP, adenosine 5'-(beta ,gamma -iminodiphosphate).
2    J.-J. Yang and R. S. Krauss, unpublished observations.

Acknowledgments

We thank Rick Assoian, Michele Pagano and Jim Roberts for gifts of antibodies. We also thank Hank Sadowski, Jim Manfredi, Xiangwei Wu, and Mark Frankel for comments on the manuscript.


REFERENCES

  1. Shin, S.-I., Freedman, V. H., Risser, R., and Pollack, R. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 4435-4439 [Abstract]
  2. Krauss, R. S., Guadagno, S. N., and Weinstein, I. B. (1992) Mol. Cell. Biol. 12, 3117-3129 [Abstract]
  3. Feinleib, J. L., and Krauss, R. S. (1996) Mol. Carcinog. 16, 139-148 [CrossRef][Medline] [Order article via Infotrieve]
  4. Guadagno, T. M., Ohtsubo, M., Roberts, J. M., and Assoian, R. K. (1993) Science 262, 1572-1575 [Medline] [Order article via Infotrieve]
  5. Kang, J.-S., and Krauss, R. S. (1996) Mol. Cell. Biol. 16, 3370-3380 [Abstract]
  6. Fang, F., Orend, G., Watanabe, N., Hunter, T., and Ruoslahti, E. (1996) Science 271, 499-502 [Abstract]
  7. Zhu, X., Ohtsubo, M., Bohmer, R. M., Roberts, J. M., and Assoian, R. K. (1996) J. Cell. Biol. 133, 391-403 [Abstract]
  8. Marshall, M. S. (1995) FASEB J. 9, 1311-1318 [Abstract/Free Full Text]
  9. White, A. M., Nicolette, C., Minden, A., Polverino, A., Van Aelst, L., Karin, M., and Wigler, M. H. (1995) Cell 80, 533-541 [Medline] [Order article via Infotrieve]
  10. Khosravi-Far, R., White, M. A., Westwick, J. K., Solski, P. A., Chrzanowska-Wodnicka, M., Van Aelst, L., Wigler, M. H., and Der, C. J. (1996) Mol. Cell. Biol. 16, 3923-3933 [Abstract]
  11. Cowley, S., Paterson, H., Kemp, P., and Marshall, C. J. (1994) Cell 77, 841-852 [Medline] [Order article via Infotrieve]
  12. Khosravi-Far, R., Solski, P. A., Clark, G. J., Kinch, M. S., and Der, C. J. (1995) Mol. Cell. Biol. 15, 6443-6453 [Abstract]
  13. Qiu, R.-G., Chen, J., Kirn, D., McCormick, F., and Symons, M. (1995) Nature 374, 457-459 [CrossRef][Medline] [Order article via Infotrieve]
  14. Qiu, R.-G., Chen, J., McCormick, F., and Symons, M. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 11781-11785 [Abstract]
  15. Dubyak, G. R., and El-Moatassim, C. (1993) Am. J. Physiol. 265, C577-C606 [Abstract/Free Full Text]
  16. Fredholm, B. B., Abbracchio, M. P., Burnstock, G., Daly, J. W., Harden, T. K., Jacobson, K. A., Leff, P., and Williams, M. (1994) Pharmacol. Rev. 46, 143-156 [Medline] [Order article via Infotrieve]
  17. Surprenant, A., Rassendren, F., Kawashima, E., North, R. A., and Buell, G. (1996) Science 272, 735-738 [Abstract]
  18. Akbar, G. K. M., Dasari, V. R., Webb, T. E., Ayyanathan, K., Pillarisetti, K., Sandu, A. K., Athwal, R. S., Daniel, J. L., Ashby, B., Barnard, E. A., and Kunapuli, S. P. (1996) J. Biol. Chem. 271, 18363-18367 [Abstract/Free Full Text]
  19. Huang, N., Wang, D., and Heppel, L. A. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 7904-7908 [Abstract]
  20. Gonzalez, F. A., Wang, D., Huang, N., and Heppel, L. A. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 9717-9721 [Abstract]
  21. Huang, N., Wang, D., and Heppel, L. A. (1993) J. Biol. Chem. 268, 10789-10795 [Abstract/Free Full Text]
  22. Yang, J.-J., Kang, J.-S., and Krauss, R. S. (1995) Oncogene 10, 1291-1299 [Medline] [Order article via Infotrieve]
  23. Schulze, A., Zerfass, K., Spitkovsky, D., Middendorp, S., Berges, J., Helin, K., Jansen-Durr, P., and Henglein, B. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 11264-11268 [Abstract]
  24. Beijersbergin, R. L., and Bernards, R. (1996) Biochim. Biophys. Acta 1287, 103-120 [CrossRef][Medline] [Order article via Infotrieve]
  25. Sherr, C. J. (1994) Cell 79, 551-555 [Medline] [Order article via Infotrieve]
  26. Heichman, K. A., and Roberts, J. M. (1994) Cell 79, 557-562 [Medline] [Order article via Infotrieve]

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