(Received for publication, September 18, 1996, and in revised form, October 9, 1996)
From the Laboratory for Physiological Chemistry, Graduate School for Developmental Biology, Utrecht University, P. O. Box 80042, 3508 TA Utrecht, The Netherlands
Ret is a receptor tyrosine kinase required during embryogenesis for the survival of enteric and sympathetic neuroblasts. Recently, glial cell line-derived neurotrophic factor (GDNF) has been identified as a ligand for Ret. We investigated early events in GDNF-induced signal transduction. We show that GDNF activates the Ras-ERK2 signaling pathway in SK-N-MC cells stably transfected with a full-length Ret construct. In addition, activation of Ret tyrosine kinase activity, either via GDNF stimulation of full-length Ret or via epidermal growth factor stimulation of an epidermal growth factor receptor-Ret chimeric receptor, results in phosphatidylinositol 3-kinase activation and phosphatidylinositol 3kinase-dependent formation of large lamellipodia. Our results indicate that GDNF can serve as a genuine ligand for Ret. In addition, we show that GDNF can induce Ret-mediated formation of lamellipodia, cell surface protrusions that are implicated in neuritogenesis.
Ret is a receptor tyrosine kinase involved in the hereditary human cancer syndromes multiple endocrine neoplasia type 2 and familiar medullary thyroid carcinoma, as well as in the hereditary human colonic aganglionosis or Hirschsprung's disease (1, 2, 3, 4). During embryonic development, Ret is involved in kidney development and in development of certain parts of the peripheral nervous system, since mice lacking functional Ret die soon after birth showing renal dysgenesis and lack of sympathetic ganglia and enteric neurons in the digestive tract (5).
Recently, GDNF1 has been identified as a ligand for Ret (6, 7, 8, 9). GDNF is a survival factor for central nervous system motor neurons (10, 11, 12) and midbrain dopaminergic neurons (13), but also for survival of different classes of neurons from the peripheral nervous system (14). Mice with a targeted deletion of the GDNF gene show a phenotype identical to that of ret knock-out mice. GDNF has been shown to induce Ret tyrosine phosphorylation, mesoderm induction in Ret-expressing Xenopus embryo cells, neurite outgrowth from autonomic neuroblasts in explants from the nephrogenic region of embryonic day 11.0-11.5 mouse embryo, and increased survival and proliferation of Ret-expressing cells (6, 8). However, the signal transduction cascades mediating these GDNF-induced effects have not been investigated in detail.
GDNF does not bind directly to Ret, but through the interaction with
GDNFR-, a glycosyl phosphatidylinositol-linked cell surface receptor
lacking a transmembrane or intracellular domain (7, 9). Indeed, Jing
et al. (9) and Treanor et al. (7) show that
Ret expression is not enough for GDNF binding, but instead GDNFR-
expression mediates GDNF binding, independent of Ret
expression. Additionally, treatment of GDNF-responsive cells with
phosphatidylinositide-specific phospholipase C, which results in
release of GDNFR-
from the membrane, results in loss of
responsiveness of Ret to GDNF. Addition of soluble forms of GDNFR-
restores this responsiveness (7, 9). Apparently, several cell types
express GDNFR-
endogenously in the absence of Ret expression, since
Trupp et al. (8) and Durbec et al. (6) showed
that introduction of Ret alone is sufficient to confer GDNF
responsiveness to different cell types.
Here we show that transfection of Ret into the human neuroepithelioma cell line SK-N-MC makes these cells responsive to GDNF. We show that GDNF induces Ret tyrosine phosphorylation and activation of the Ras-ERK2 pathway, which is not observed in the parental cell line. In addition, Ret induces PI3K activity, followed by PI3K-dependent formation of large lamellipodia. As lamellipodia formation is implicated in neuritogenesis, Ret signaling via PI3K may mediate neurite outgrowth as observed in GDNF-stimulated neuroblasts (6).
The human neuroepithelioma cell line SK-N-MC and its stably transfected subclones were cultured in DF12 medium supplemented with antibiotics and 10% fetal calf serum. The full-length Ret-expressing cell line SKP2 was generated by stable transfection of Ret-negative SK-N-MC cells with an Rc/CMV-Ret expression plasmid (kindly provided by M. Takahashi (Nagoya University School of Medicine, Nagoya, Japan); Ref. 15), encoding the p9 form of Ret.
Analysis of the Ras-ERK2 PathwayExperimental procedures for the analysis of the Ras-ERK2 pathway have been described previously (16).
ImmunofluorescenceCells were grown on glass coverslips and serum-starved overnight. After a 10 min incubation of the cells with GDNF (Pepro Tech) or EGF (Sigma), either with or without a 10-min pretreatment with the PI3K inhibitors wortmannin (Sigma) or LY294002 (Sigma), cells were fixed for 20 min in PBS containing 4% paraformaldehyde and permeabilized with 0.1% Triton X-100 in PBS, and nonspecific binding was blocked by incubation with PBS containing 0.5% bovine serum albumin for 45 min. Coverslips were then incubated for 2 h at room temperature with FITC-coupled phalloidin (Sigma), which specifically binds to polymerized actin. After three washes in PBS, the coverslips were embedded in Immumount (Shandon) and analyzed using a Labophot fluorescence microscope (Nikon).
In Vitro PI3K AssayTo determine PI3K activity in the cells, serum-starved cells were either left untreated or stimulated for 5 min with 40 ng/ml EGF or 100 ng/ml GDNF. Cells were lysed in a buffer containing 20 mM Tris-HCl (pH 8.0), 137 mM NaCl, 10% glycerol, 1% Nonidet P-40, 1 mM MgCl2, 2 mM EDTA, 0.1 µM aprotinin, 1 µM leupeptin, 1 mM orthovanadate, and 1 mM phenylmethylsulfonyl fluoride. Tyrosine-phosphorylated proteins were immunoprecipitated for 2 h at 4 °C using an anti-phosphotyrosine antibody (FB2) coupled to protein A-Sepharose beads. After extensive washing, beads were taken up into kinase assay buffer (30 mM Hepes (pH 7.4), 30 µM adenosine, 0.1 mg/ml phosphatidylinositol), followed by incubation for 20 min at room temperature. Subsequently, ATP and MgCl2 were added to a final concentration of 40 µM and 30 mM, respectively, followed by an additional incubation for 25 min at room temperature. The kinase reaction was stopped by addition of 2 volumes of 1 M HCl, lipids were isolated using methanol and chloroform, and separated by thin layer chromatography. Chromatograms were exposed to a PhosphorImager screen. Fold inductions of PI3K activity were calculated relative to the unstimulated situation.
Recently, several groups have
implicated GDNF as a ligand for the receptor tyrosine kinase Ret
(6, 7, 8, 9). To study early signal transduction events after GDNF-stimulated
Ret tyrosine kinase activity, we used the Ret-negative neuroepithelioma cell line SK-N-MC stably transfected with a full-length Ret expression plasmid (SKP2 cell line). Stimulation of SKP2 cells with different concentrations of GDNF resulted in a
concentration-dependent tyrosine phosphorylation of the
170-kDa plasma membrane-bound isoform of Ret (Fig. 1).
Maximal Ret tyrosine phosphorylation levels were induced with GDNF
concentrations between 40 and 160 ng/ml, which is identical to
concentrations reported by others for stimulation of Ret (and
GDNFR-)-expressing cells (6, 7, 8, 9). The 150-kDa isoform of Ret, which
is not present at the plasma membrane (15, 17), is not phosphorylated
in response to GDNF stimulation (Fig. 1). From these results we
conclude that GDNF can induce autophosphorylation of the receptor
tyrosine kinase Ret in the SKP2 cell line.
GDNF Induces Activation of the Ras-ERK2 Pathway
GDNF has been
suggested to induce activation of mitogen-activated protein kinases
since it induces mesoderm formation in Ret-expressing embryonic
Xenopus cells as well as increase proliferation of
Ret-expressing cells (6, 7, 8). To investigate whether GDNF indeed
directly activates the Ras-ERK2 signaling pathway, we analyzed GDNF
signaling toward ERK2 in SKP2 cells. We first analyzed the effect of
GDNF on Shc phosphorylation. As shown by Shc or phosphotyrosine
immunoprecipitations followed by immunoblotting with
anti-phosphotyrosine or anti-Shc antibodies, respectively, GDNF induces
specific tyrosine phosphorylation of the 66-, 52-, and 46-kDa forms of
Shc in SKP2 cells (Fig. 2A).
GDNF induces Ret-dependent activation of the Ras-ERK2 signaling pathway. A, GDNF induces Shc phosphorylation. Serum-starved SK-N-MC and SKP2 cells were stimulated with 100 ng/ml GDNF or 20 ng/ml basic fibroblast growth factor (included as a positive control) as indicated, followed by immunoprecipitation (i.p.) of tyrosine-phosphorylated proteins and immunoblotting with an anti-Shc antibody (upper panel), or immunoprecipitation of Shc proteins and immunoblotting with an anti-phosphotyrosine antibody (lower panel). PY, phosphotyrosine; G, GDNF; F, basic fibroblast growth factor. B, GDNF induces a small Ras activation. Serum-starved, 32P-labeled SK-N-MC, SKP2, and SKF5 cells were stimulated with 100 ng/ml GDNF or 40 ng/ml EGF, followed by isolation of guanine nucleotides bound to Ras. Bars represent the fold induction in GTP-bound Ras after growth factor stimulation. C, GDNF induces ERK2 activation. Serum-starved SK-N-MC and SKP2 cells were stimulated with the indicated concentration of GDNF for 10 min, followed by lysis of the cells and immunoblotting with an antibody against ERK2. Position of the inactive (ERK2) and active (ppERK2) form of ERK2 are indicated. D, GDNF-induced ERK2 activation is dependent on Ras. SKP2 cells were transfected with a tagged ERK2 construct in the absence or presence of a dominant negative mutant of Ras (Ras-N17). After stimulation with 100 ng/ml GDNF as indicated, tagged ERK2 was immunoprecipitated and ERK2 activity was determined in an in vitro kinase assay with myelin basic protein as a substrate. Bars represent the fold induction of ERK2 activity after GDNF stimulation.
We next analyzed the activation of Ras, by measuring the ratio of Ras bound to GDP and GTP before and after GDNF stimulation of SKP2 cells. A consistent, yet small increase in Ras bound to GTP was observed in three independent experiments (Fig. 2B). This increase was not observed in the parental SK-N-MC cells treated with GDNF. The activation of Ras after EGF stimulation of the HERRet chimeric receptor, was more pronounced, i.e. a 2-3-fold increase (Fig. 2B).
Finally, we analyzed whether GDNF stimulation of SKP2 cells leads to ERK2 activation. As shown in Fig. 2C, GDNF induced a concentration-dependent ERK2 activation, as determined by a shift in mobility of the activated form of ERK2. The ERK2 mobility shift was maximal between 40 and 160 ng/ml GDNF. This correlates well with tyrosine phosphorylation of the 170-kDa isoform of Ret at these concentrations (Fig. 1). ERK2 activation after GDNF stimulation of SKP2 cells was completely inhibited by transient transfection of a dominant negative mutant of Ras (Ras-N17), showing that the small increase in Ras GTP following GDNF stimulation is sufficient for ERK2 activation (Fig. 2D).
GDNF-induced activation of the Ras-ERK2 pathway is specifically mediated by the Ret tyrosine kinase, since GDNF stimulation of the parental Ret-negative SK-N-MC cells did not induce protein-tyrosine phosphorylation, Shc phosphorylation, Ras activation, or ERK2 activation (Fig. 2).
Ret Tyrosine Kinase Activation Induces PI3K Activity and PI3K-dependent Lamellipodia FormationGDNF has been
shown to induce neurite outgrowth from nephrogenic explants of
heterozygous, but not homozygous, ret knock-out mice,
indicating that GDNF-activated Ret is involved in neurite outgrowth.
Since the actin cytoskeleton is involved in neurite formation, we
investigated the effect of Ret activation on the actin cytoskeleton of
stably transfected SK-N-MC cells. This was tested both in SKP2 cells as
well as in SKF5 cells, which are SK-N-MC cells stably transfected with
the HERRet chimeric receptor (16). When SKF5 cells were grown in the
presence of 0% or 10% serum, several actin-rich cell surface
protrusions were present on the cells, as could be seen after staining
of the cells with FITC-labeled phalloidin, which specifically
recognizes polymerized actin (Fig. 3A). Time
lapse video microscopy of living SKF5 cells revealed that these
protrusions are continuously formed and retracted by the cells, and
thus resemble the filopodia observed at the growth cone of an axon (18,
19). Addition of EGF to activate the Ret tyrosine kinase resulted in
the formation of large lamellipodia (Fig. 3B). These
lamellipodia were observed within 5 min in more than 90% of the cells
at the border of a cell cluster. Lamellipodia were observed for at
least 30 min. Time lapse video microscopy revealed that after
stimulation lamellipodia are formed by filling in the space between
filopodia, which gradually decrease in length and disappear.
Dose-response analysis showed that lamellipodia are already formed at
2.5 ng/ml EGF, which corresponds to the minimal concentration necessary
for Ret autophosphorylation and ERK2 activation (data not shown).
In a concentration-dependent manner, GDNF also induced lamellipodia formation in SKP2 cells. Using 160 ng/ml, approximately 70% of the cells at the border of a cell cluster showed lamellipodia formation (Fig. 3D). At lower concentrations fewer cells responded, with a minimum of 10 ng/ml for the induction of lamellipodia. This also correlates with the minimum concentration of GDNF required for induction of tyrosine phosphorylation on Ret (Fig. 1).
Lamellipodia formation or membrane ruffling in non-neuronal cell lines
is dependent on, and mediated by, PI3K activity (20, 21, 22). Additionally,
neurite outgrowth in neuronal PC12 cells is dependent on PI3K activity
(23). To establish the role of PI3K in Ret-induced lamellipodia
formation, we first determined the effect of Ret activation on PI3K
activity. As shown in Fig. 4, stimulation of SKF5 cells
with EGF resulted in a clear activation of PI3K activity. In addition,
GDNF stimulation of full-length Ret in SKP2 cells induced PI3K
activation (Fig. 4). In the parental SK-N-MC cell line, EGF or GDNF
treatment did not induce PI3K activation. These results show that Ret
tyrosine kinase activation results in PI3K activity.
Using two different PI3K inhibitors, wortmannin and LY294002, we
investigated the role of PI3K in Ret-induced lamellipodia formation.
Pretreatment of SKF5 or SKP2 cells with wortmannin (Fig.
5) or LY294002 (data not shown) followed by stimulation of Ret tyrosine kinase activity with EGF or GDNF, respectively, resulted in a complete inhibition of lamellipodia formation. Titration experiments showed that pretreatment with 25 nM wortmannin
is sufficient to completely inhibit PI3K- and Ret-induced lamellipodia formation (data not shown). These results show that PI3K activity is
essential for Ret-induced lamellipodia formation.
Signal transduction toward lamellipodia formation in the SK-N-MC-derived SKF5 and SKP2 cell lines is mediated specifically by Ret, since stimulation of the parental SK-N-MC cell line with either EGF or GDNF did not induce changes in the actin cytoskeleton (Fig. 3).
Recently, GDNF has been identified as a ligand for the receptor tyrosine kinase Ret. With respect to effects of GDNF on cells, only late effects, such as increased proliferation or survival and induction of differentiation, have been documented (6, 7, 8, 9, 14, 24, 25). In this paper we describe early events in GDNF-induced signal transduction. GDNF-induced signaling was investigated in stable transfectants of the SK-N-MC neuroepithelioma cells line expressing full-length Ret. We show that GDNF stimulation of SKP2 cells results in a concentration-dependent induction of Ret tyrosine phosphorylation, followed by Shc phosphorylation and Ras and ERK2 activation. Although GDNF treatment of SKP2 cells only results in a small increase in Ras activity, it is clearly essential for the activation of ERK2, since expression of dominant negative Ras-N17 inhibits ERK2 activation completely. A similar situation was shown previously for platelet-derived growth factor, which also induces only a small increase in GTP-bound Ras that is, however, sufficient for ERK2 activation (26). In addition, we show that Ret tyrosine kinase activity, activated by GDNF stimulation of full-length Ret or by EGF stimulation of HERRet, induces PI3K activity. PI3K activation by receptor tyrosine kinases has now been shown for several other receptors, including the platelet-derived growth factor receptor, insulin receptor, insulin-like growth factor receptor, and hepatocyte growth factor receptor (27, 28, 29, 30). Ret-induced activation of PI3K mediates the formation of lamellipodia in both SKP2 and SKF5 cells. It is now well established that for lamellipodia formation or membrane ruffling PI3K activity is essential. This has been shown by the use of mutant receptors that fail to bind the p85 regulatory subunit of PI3K, the use of dominant negative mutants of p85, and by the use of two specific PI3K inhibitors, wortmannin and LY294002 (20, 21, 22, 29, 31). Indeed, treatment of SKP2 or SKF5 cells with wortmannin or LY294002 completely inhibited Ret-induced lamellipodia formation, confirming the role for PI3K in this response. The responses described in this paper are specifically mediated by Ret since GDNF or EGF stimulation of the Ret-negative parental SK-N-MC cell line did not result in any of the described signaling events.
The signals induced by GDNF in full-length Ret-expressing SKP2 cells
are, in general, weaker than those induced by EGF stimulation of
HERRet-expressing SKF5 cells. This may be due to the number of
receptors expressed on the SKP2 cell surface, which is at least 10-fold
lower than HERRet expression in SKF5 cells. The concentration of GDNF
necessary to induce Ret-mediated responses in SKP2 cells, 10 ng/ml, is
in the same order of magnitude as the concentration used by others for
stimulation of cell lines or primary neurons, including those cell
lines that express high levels of GDNFR- (6, 7, 8, 9, 14, 32, 33). We
therefore conclude that, if GDNFR-
is essential for GDNF-induced Ret
activation, SKP2 cells express sufficient GDNFR-
molecules. However,
it should be noted that Mount et al. (24) reported increased
proliferation of primary Purkinje cells using GDNF concentrations as
low as 1 pg/ml.
Ret signal transduction has also been investigated in a fibroblast cell line stably transfected with a HERRet expression vector (34). In these cells, Ret tyrosine kinase activity induces Ras activation, but not ERK2 activation, which is in clear contrast to results obtained in both GDNF-stimulated SKP2 cells, as shown in this paper, and EGF-stimulated SKF5 cells (16). In addition, Santoro et al. concluded that in fibroblasts Ret activation does not induce PI3K activity. Also this signaling pathway is activated after Ret activation in SK-N-MC-derived cell lines. Clearly, Ret signaling in fibroblasts is different from Ret signaling in neuronal cells, the cell type in which Ret is normally expressed.
In neuronal cells, lamellipodia formation is a critical event in neuritogenesis. Lamellipodia formation is observed at growth cones of neurites, and inhibition of lamellipodia formation with actin polymerization inhibitors or PI3K inhibitors blocks neurite outgrowth (18, 19, 23, 35, 36). Lamellipodia formation has also been implicated in cellular migration (37). We have shown here that activation of Ret tyrosine kinase activity, either by GDNF stimulation of full-length Ret or by EGF stimulation of HERRet, results in the formation of large lamellipodia. These lamellipodia may represents early events in neurite formation. Indeed, expression of constitutively active Ret in PC12 cells induces neurite outgrowth (38). In addition, autonomic neuroblasts in explants from the nephrogenic region of embryonic day 11.0-11.5 mouse embryos show Ret-dependent axonal outgrowth toward beads soaked in GDNF (6). Alternatively, Ret-induced lamellipodia may be involved in migration of neuronal precursors. However, it has been shown that Ret expression is up-regulated only after migration of neuroblasts toward the rat fetal gut. In addition, detailed analysis of ret knock-out mice showed that Ret-negative neuroblasts do migrate into the anlage for enteric and sympathetic ganglia, despite the lack of expression of functional Ret (39, 40). It is only after reaching the anlage that the Ret-negative neuroblasts die (40). Death of these cells may be the result of the inability of the neuroblasts to form connections with target cells because of the failing neuritogenesis in the absence of functional Ret. Neuroblasts that cannot form functional contacts with target cells die because of deprivation of neurotrophic factors (for review see Ref. 41).
We thank M. Takahashi for the Rc/CMV-Ret expression plasmid and Catherine Nobes for help with the time-lapse video microscopy analysis. We also thank Alan Hall, Peter Burbach, and Piet Baas for discussions and our colleagues for critical reading of the manuscript.