(Received for publication, December 17, 1996, and in revised form, January 31, 1997)
From the Department of Pharmacology, School of Medicine, University of North Carolina, Chapel Hill, North Carolina 27599
Cell anchorage strongly affects the signal transduction cascade initiated by peptide mitogens. For both epidermal growth factor and platelet-derived growth factor, activation of the consensus mitogen-activated protein kinase cascade is impaired when cells are held in suspension as compared with cells anchored to a fibronectin substratum. Upstream events in the signaling cascade, including tyrosine phosphorylation of the mitogen receptor and GTP loading of Ras, are similar in anchored and suspended cells. However, propagation of the signal to Raf and subsequently to the downstream kinases MEK and mitogen-activated protein kinase is markedly attenuated in suspended cells. Thus, there seems to be a distinct anchorage-dependent step between Ras and Raf in the signaling cascade initiated by peptide mitogens. These observations may have important implications for understanding the anchorage dependence of cell growth.
Cell anchorage to the proteins of the extracellular matrix is known to have profound effects on cell differentiation (1, 2), cell growth (3), and apoptosis (4). A particularly important example of this concerns the recently described effects of anchorage on the expression and activity of components of the cell cycle machinery, including cyclin D1-CDK4,6 complexes and cyclin E-CDK2 complexes (5, 6). These observations are clearly relevant to the question of why both soluble mitogens and cell anchorage are required for the growth of normal cells, whereas the anchorage requirement is abrogated in transformed cells (7). Many aspects of cell to extracellular matrix interactions involve the integrin family of cell surface heterodimeric adhesion proteins (8). Recently, it has become clear that integrins are signal transducing receptors (9, 10) capable of influencing a number of intracellular biochemical activities including protein tyrosine kinases (11), serine/threonine kinases (12), and ionic transients (13). In particular, integrin-mediated cell adhesion can trigger activation of MAP1 kinase (14-16) and of other protein kinases (17) that are part of the consensus signaling pathway leading from receptor tyrosine kinases to Ras and then to a cytoplasmic kinase cascade comprising Raf, MEK1, MEK2, and MAP kinases (18).
Because integrins directly activate elements of the MAP kinase cascade, it is of interest to ask whether integrin-mediated cell anchorage can also regulate the action of soluble mitogens on this cascade. If this were so, it would have important ramifications for understanding the anchorage dependence of cell cycle traverse. Previous studies of possible collaboration between peptide mitogens and cell anchorage have led to differing results. In some cases an enhancement of mitogen signaling was observed in anchored cells as compared with their counterparts maintained in suspension, whereas in other cases no such effect was observed (19-22). In the present investigation we have studied the collaboration between mitogens and anchorage in NIH 3T3 cells, a cell type that has been widely used in signal transduction studies. We have examined several steps in the signal transduction pathway leading from receptor tyrosine kinases to Ras and then to the downstream kinases. We find that peptide mitogen activation of receptor tyrosine kinases and subsequent activation of Ras are independent of anchorage. However, signal transduction between Ras and Raf is markedly attenuated in nonadherent cells, leading to reduced activation of Raf, MEK, and MAP kinase.
NIH 3T3 cells were maintained in Dulbecco's minimal essential medium containing 10% bovine calf serum and antibiotics. Confluent cells were serum-starved for 16 h before detachment by 0.05% trypsin and 0.33 mM EDTA; trypsin activity was neutralized by 1 mg/ml soybean trypsin inhibitor. Cells were suspended in Dulbecco's minimal essential medium with 2% bovine serum albumin and incubated in suspension at 37 °C for 45 min in a rotator to allow kinases become quiescent. Cells were then either maintained in suspension or plated onto dishes coated with fibronectin (20 µg/ml) or with poly-L-lysine (20 µg/ml) and incubated at 37 °C for the indicated times. In some cases the suspended or adherent cells were stimulated with either EGF or PDGF (Upstate Biotechnologies Inc.). Cell lysates were prepared and tested for the activity of Raf, MEK, and MAP kinase using specific in vitro kinase assays as described previously (17). The phosphorylation status of the EGF receptor and PDGF receptor were evaluated by immunoprecipitation of the receptor using antibodies obtained from H. S. Earp (EGF-R) or from Santa Cruz Biotechnology (PDGF-R) followed by Western blotting with an anti-phosphotyrosine antibody and detection by enhanced chemiluminescence (17). For studies of GTP loading of the Ras protein, cells were radiolabeled with [32P]orthophosphate, and the [32P]GTP and GDP bound to immunoprecipitated Ras were quantitated by thin layer chromatography and PhosphorImager analysis as described (17).
Because elements of the MAP kinase cascade are directly but
transiently activated by integrin-mediated cell adhesion (17), we
initially examined the kinetics of this process to find a time point
when we could examine anchorage effects on mitogen-driven activation of
MAP kinase without a direct contribution from integrin-mediated MAP
kinase activation. As seen in Fig. 1 (A and
B), when NIH 3T3 cells were held in suspension, EGF caused a
robust tyrosine phosphorylation of EGF-R but had only a very modest
effect on MAP kinase (Fig. 1B, lanes 1 and
2). After 10 min of cell adhesion to fibronectin-coated substrata, when the cells were fully attached but not spread, there was
a strong adhesion-mediated activation of MAP kinase; EGF stimulation
caused tyrosine phosphorylation of EGF-R and further stimulated MAP
kinase (Fig. 1B, lanes 3 and 4). A
qualitatively similar situation also prevailed after 30 min of cell
adhesion when the cells were partially spread (Fig. 1B,
lanes 5 and 6). By 180 min, when the cells were
well spread, in the absence of EGF there was only a basal level of MAP
kinase activity, whereas treatment with EGF caused tyrosine
phosphorylation of EGF-R and resulted in a strong stimulation of MAP
kinase (Fig. 1B, lanes 7 and 8). Thus,
in serum-starved 3T3 cells, EGF activation of its receptor seems to be
independent of cell anchorage; however, the MAP kinase response is
strongly influenced by anchorage. In nonadherent cells, EGF produces
only a weak activation of MAP kinase. Shortly after the cells adhere to
the fibronectin substratum, EGF and anchorage have approximately
additive effects on MAP kinase activity. At longer times, EGF strongly
activates MAP kinase in anchored cells, whereas the direct activation
by cell adhesion has returned to basal levels. In Fig. 1 (C
and D) we examined EGF concentration-response relationships
for EGF-R and MAP kinase in cells that have either been maintained in
suspension or anchored to fibronectin for 180 min. As shown, the
concentration-response profile for EGF-R tyrosine phosphorylation was
essentially identical in suspended cells and cells anchored to
fibronectin substrata. However, at all EGF concentrations tested,
anchored cells displayed a 3-4-fold greater activation of MAP kinase
than did suspended cells (for example, compare lanes 4 and
10 in Fig. 1D, both at 5 ng/ml EGF).
We have also investigated how anchorage modulates mitogen actions on
other components of the MAP kinase cascade. As shown in Fig.
2A, EGF stimulated similar levels of tyrosine
phosphorylation of EGF-R in suspended or anchored cells. However, EGF
produced substantially stronger activations of Raf-B, MEK, and MAP
kinase in cells anchored to fibronectin substrata as compared with
nonanchored cells. Raf-1 was also activated (weakly) by EGF in anchored
cells but not in suspended cells (not shown). We decided to also
examine anchorage dependence of signaling events mediated by PDGF,
another peptide mitogen. Exposure of 3T3 cells to PDGF caused a
substantially greater increase in overall cellular protein tyrosine
phosphorylation than was observed with EGF (not shown). As seen in Fig.
2B, PDGF caused equivalent robust tyrosine phosphorylation
of its cognate receptor in both anchored and suspended cells. However,
PDGF treatment resulted in markedly stronger activation of Raf-1 and
MEK in anchored cells as compared with suspended cells, as well as a
more modest but significant difference in MAP kinase activation. Thus,
for PDGF, as for EGF, cell anchorage seems to control the efficiency of
signal transduction between initial activation of the receptor tyrosine
kinase and subsequent activation of downstream kinases.
Because the GTP-bound form of Ras is a key transducer in the mitogen
signaling pathway (18), we decided to examine Ras GTP loading in
anchored or suspended 3T3 cells treated with either PDGF or EGF. As
seen in Fig. 3, the basal GTP/GDP ratio was somewhat higher in suspension cells than in adherent cells. Treatment with peptide mitogen resulted in a strong increase in Ras GTP loading in
both suspended cells and anchored cells, with PDGF producing a somewhat
greater effect than EGF. Thus, Ras GTP loading in response to mitogens
occurred in suspended cells at least as well as in anchored cells; in
fact, suspended cells usually showed higher levels of GTP loading than
anchored cells. This observation, along with those of Fig. 2, suggests
that peptide mitogen signaling pathways are intact and operate
efficiently in both suspended and anchored cells up to the level of Ras
but are attenuated between Ras and the Raf kinases in the nonanchored
cells.
Quantitation of anchorage effects on activation of several components
of the EGF- and PDGF-triggered pathways is shown in Fig.
4. The data are expressed as the ratio of the mitogen
activation in suspended cells versus anchored cells. The
downstream kinases (Rafs, MEKs, and MAP kinases) display substantial
reductions in activity in nonanchored cells, but Ras and the receptor
tyrosine kinases do not. Although the exact magnitudes of the anchorage effects on activation of the individual components of the pathway differ somewhat between EGF and PDGF, the trend is similar. The observation that EGF and PDGF produce qualitatively similar but quantitatively distinct effects on the consensus MAP kinase cascade is
not surprising, because individual receptor tyrosine kinases are known
to have distinct effects on cell growth and differentiation (23).
Although cell anchorage to a fibronectin-coated substratum clearly has a substantial impact on the MAP kinase cascade, it is not yet certain that this is purely an integrin-mediated phenomenon. Preliminary experiments have shown that EGF activation of MAP kinase is 2-3-fold greater in cells plated on a fibronectin substratum, as opposed to a poly-lysine substratum (data not shown). This suggests that the anchorage effects on signaling that we have observed may be mediated by integrins; however, several additional lines of investigation will be needed to fully confirm this possibility.
Anchorage dependence of cell growth is one of the most fundamental differences between normal and transformed cells (24). Our observations indicate that cell anchorage can influence the efficiency of signal tranduction in mitogenic pathways. This suggests the possibility that adhesion effects on early signaling events may play an important role in anchorage dependence of cell growth, although other factors may also be involved. For both EGF and PDGF, the upstream events of the mitogen signaling pathway were independent of anchorage. Thus, receptor tyrosine kinase activation and GTP loading of Ras were robust in both anchored and suspended cells. For both mitogens, however, cell adhesion had a profound effect on the activation of the MEK-kinases Raf-B and Raf-1 and clear-cut effects of lesser magnitude on MEK and MAP kinase. The nonlinearity of the effects we have observed on anchorage regulation of signal transduction may be due to the extensive branching and cross-talk that is known to occur in the MAP kinase cascade (25). Our observations suggest that in suspended cells, there is a rather sharp break in the signaling cascade between Ras and the Raf kinases. Because a major role of Ras in signal transduction is to recruit Raf to the plasma membrane (26), our findings suggest that cell anchorage contributes to this process. One plausible model is that integrin-dependent focal contacts formed during cell adhesion participate in the recruitment and subsequent activation of Raf.
Cell anchorage to fibronectin, a process primarily mediated by integrins, resulted in 2-3-fold greater activation of MAP kinases by peptide mitogens as compared with suspended cells. At this point it is unclear whether a change in MAP kinase activation of this magnitude would account for the strong effect that anchorage has on cell growth. It is important to note, however, that the effects of anchorage on Raf-1 or Raf-B activation were much greater (8-20-fold). Raf family kinases are thought to have downstream targets other than the MAP kinase pathway (27, 28). Thus, it seems possible that the anchorage modulation of mitogen signaling reported here, particularly the dramatic effect on Raf family kinases, may be important aspects of cell growth control.
We thank Andrew Aplin and Channing Der for valuable comments on the manuscript.