ADP-ribosylation Factor 4 Small GTPase Mediates Epidermal Growth Factor Receptor-dependent Phospholipase D2 Activation*

Sung-Woo Kim, Masaaki Hayashi, Jeng-Fan Lo, Young YangDagger , Jin-San Yoo§, and Jiing-Dwan Lee

From the Departments of Immunology and § Cell Biology, The Scripps Research Institute, La Jolla, California 92037 and Dagger  Johnson & Johnson Pharmaceutical Research and Development, San Diego, California 92121

Received for publication, June 12, 2002, and in revised form, November 18, 2002

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The epidermal growth factor receptor (EGFR) plays a critical role in the development, proliferation, and differentiation of cells of epithelial and mesenchymal origin. These EGFR-dependent cellular processes are mediated by a repertoire of intracellular signaling pathways triggered by the activation of the EGFR cytoplasmic domain, which originates from ligand binding of its extracellular domain. To understand the molecular mechanisms by which the intracellular domain of EGFR transmits mitogenic messages to the downstream signaling pathways, we used the cytoplasmic region of EGFR as bait in yeast two-hybrid screening. We found that ADP-ribosylation factor 4 (ARF4) interacts with the intracellular part of EGFR and mediates the EGF-dependent cellular activation of phospholipase D2 (PLD2) but does not mediate the activation of PLD1. In addition, ARF4-mediated PLD2 activation leads to dramatic activation of the transcription factor activator protein 1 (AP-1), and, importantly, ARF4 activity is required for EGF-induced activation of cellular AP-1. Our findings indicate that ARF4 is a critical molecule that directly regulates cellular PLD2 activity and that this ARF4-mediated PLD2 activation stimulates AP-1-dependent transcription in the EGF-induced cellular response.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Overexpression of EGFR1 and EGF, as well as constitutive activation of mutant EGFR, give rise to the deregulation of this EGFR-dependent signaling network, which is involved in the development and malignancy of numerous types of human cancers, including cancer of the head and neck, lung, bladder, breast, colon, prostate, kidney, ovary, brain, and pancreas (1). The EGF receptor is the prototypical receptor with intrinsic protein tyrosine kinase activity (2-4). Upon ligand binding by its extracellular domain, EGFR forms homodimers or heterodimers with the closely related ErbB receptors (such as ErbB2/Her2) and begins tyrosine autophosphorylation of its cytoplasmic domain (2-4). This autophosphorylation of the intracellular domain of EGFR is critical for signal transduction, since it creates docking sites for various signaling molecules, such as molecules containing Src homology 2 or phosphotyrosine binding domains. These interactions with downstream molecules create signaling complexes that lead to oncogenic responses by linking EGFR activation to numerous cytoplasmic signaling pathways (2-4). In cancer cells, the signaling domain of EGFR mediates and regulates the proliferative signals generated from this receptor. Therefore, identifying molecules that interact with the signaling domain of EGFR will contribute not only to the elucidation of the regulatory mechanism of EGFR in cancer progression but also to the development of new treatments for uncontrolled growth of human cancers.

To further understand the molecular mechanisms by which the intracellular region of EGFR transmits signals to various intracellular signaling pathways, we used the cytoplasmic domain of EGFR as bait in yeast two-hybrid screening of a human carcinoma cDNA library. Here we identify an intracellular protein ARF4 that interacts with the cytoplasmic domain of EGFR. ARFs, members of the Ras superfamily, are small 20-kDa guanine nucleotide-binding proteins. The inactive GDP-bound form of ARF is soluble, although it can weakly associate with the cell membrane. On the other hand, the active GTP-bound form binds tightly to the membrane (5). On the basis of deduced amino acid sequences and phylogenetic analysis, ARFs have been divided into three classes: class I (ARF1, -2, and -3), class II (ARF4 and -5), and class III (ARF6) (6). Although all three classes of ARF proteins are capable of activating cellular phospholipase D, the specific roles of each ARF seem to be different. Class I is involved in the trafficking pathway that links the endoplasmic reticulum, Golgi, and endosomal systems, and class III, instead, takes part in the trafficking pathway that links the endosome and plasma membrane system (7). Many researchers believe that class II ARFs are only supplementary to class I ARFs and, as such, have focused their attention on class I ARFs while nearly ignoring the cellular functions of the class II ARF4 and ARF5 proteins. Here, we show that EGF does not activate PLD1 but does activate cellular PLD2 through the activation of ARF4. Moreover, this ARF4-dependent activation of PLD2 is required for inducing the EGF-induced transcriptional activity of activator protein 1 (AP-1).

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Yeast Two-hybrid Screening-- The EcoRI fragment encoding the cytoplasmic domain of EGFR was fused in frame with the GAL4 DNA binding domain (BD) of the pGBKT7 fusion vector (Clontech) to create the BD/EGFR construct. A human epithelial carcinoma cDNA library was separately fused with the GAL4 activation domain (AD) of the pGAD-GH vector (Clontech). The yeast strain pJ69-2A was co-transformed, by a lithium acetate-based method, with this library and the BD/EGFR construct. The transformed yeast cells were screened, according to the manufacturer's protocols, for their ability to grow on plates lacking histidine and adenine.

DNA Constructs-- PCR was used to obtain full-length cDNAs encoding ARF4, PLD1, PLD2, and EGFR by use of the Rapid-ScreenTM arrayed human placenta cDNA library, which is constructed in the pCMV6-XL4 (ORIGENE, Rockville, MD) vector. The ARF4 wild-type and mutant cDNA fragments were cloned either into the mammalian expression vector pEBG, which also encodes the glutathione S-transferase tag (8), or into the multiple cloning site of the vector pRK5, which encodes three copies of the hemagglutinin (HA) epitope at its carboxyl terminus (9). All mutations in the ARF4 gene were generated by PCR-based mutagenesis as previously described (9).

Cell Lines and Culture Conditions-- 293T cells overexpressing EGFR (293T/EGFR) were obtained by transfecting, via the calcium phosphate method, the hygromycin selection vector pCMV6-XL4 into 293T cells, which express undetectable levels of endogenous EGFR. Transfected cultures were selected with hygromycin (300 µg/ml) for 10-14 days at 37 °C. All cells were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum (HyClone) as described previously (10). Cells were grown to subconfluence and then starved overnight by replacing medium with serum-free Dulbecco's modified Eagle's medium supplemented with 2 mM glutamine and nonessential amino acids before initiating the 30-min stimulation with EGF (50 ng/ml).

Immunoprecipitation-- Cells were solubilized in lysis buffer containing 2 mM HEPES (pH 7.6), 1% Triton X-100, 137 mM NaCl, 0.1 mM Na3VO4, 25 mM beta -glycerophosphate, 3 mM EDTA, and 1 mM phenylmethylsulfonyl fluoride as described (10, 11). Cell lysates were then incubated with protein G-coupled Sepharose beads (Amersham Biosciences) for 1 h, after which the beads were discarded, and the supernatants were incubated with specific antibodies (2 µg/ml anti-EGFR antibody or IgG from preimmune serum) for 1 h followed by overnight incubation with protein G-agarose at 4 °C. Samples were collected and washed four times with lysis buffer. The precipitated samples were analyzed by Amersham Bioscience's ECL blotting system with specific antibodies (200 ng/ml unless mentioned). The R891 anti-ARF4 antiserum and monoclonal 1D9 antibody against the other ARFs (ARF1, -3, -5, and -6) were kindly provided by Dr. R. A. Kahn (7) and used for probing immunoblots for endogenous ARFs.

Immunofluorescence-- Cells were plated on 25-mm coverslips (Fisher). After transient transfection experiments, cells were fixed with 4% formaldehyde for 15 min, washed three times with PBS, and permeabilized in PBS containing 0.5% Triton X-100 for 5 min. Cells were washed three times in PBS containing 3% bovine serum albumin for 1 h. The anti-EGFR antibody and anti-HA antibody were added to cells in PBS containing 3% bovine serum albumin for 1 h, washed four times with PBS, then incubated 1 h with Alexa Fluor 568 goat-anti-rabbit (red-orange) or Alexa Fluor 488 anti-mouse antibody (green) (Molecular Probes, Inc., Eugene, OR). Cells were washed and mounted on coverslips with Prolong (Molecular Probes) mounting medium for immunofluorescence.

Digitonin Treatment-- Briefly, 293T/EGFR cells were transfected with the plasmid expressing wild-type ARF4 with three HA tags at its C terminus. After serum starvation, cells were scraped gently and resuspended in PBS. The samples were treated with 8 µM digitonin (WAKO Chemicals, Richmond, VA), in the presence of GTPgamma S (100 µM) with or without EGF (100 ng/ml) at 37 °C for 20 min. ATP (1 mM) and magnesium (2 mM) were included in all experiments. Intracellular proteins were released from digitonin-treated cells by microcentrifugation for 20 min. Supernatants and pellets were collected separately and resolved by SDS-PAGE. The ARF4-HA3 protein was detected by probing immunoblots with the anti-HA antibody.

Membrane Preparations-- Cell membranes were prepared from ten 150-mm dishes of confluent cells. Cells were washed in PBS, scraped, and centrifuged. Pellets were resuspended in 50 mM HEPES (pH 7.6), 8% sucrose, 10 mM EDTA, 10 mM EGTA, and 1 mM phenylmethylsulfonyl fluoride and then disrupted with a glass homogenizer. Cell extracts were layered onto a 41% sucrose cushion and centrifuged at 95,000 × g for 90 min. Membrane material at the interface was collected, diluted to 10 ml, and centrifuged at 60,000 × g for 60 min. Membrane pellets were resuspended in 50 mM HEPES for the following ARF activation assays.

ARF Activation Assays-- For the nucleotide binding assay, recombinant human ARF4 (2.5 µg) was incubated at 37 °C with [35S]GTPgamma S, with or without EGF, in the presence of membranes as previously described (5). Protein-bound nucleotides were separated by filtration through nitrocellulose filters. Bound nucleotide was determined by scintillation counting. Nonspecific binding was determined by using excess, unlabeled GTPgamma S.

PLD Assays-- Cells were starved and labeled overnight with [3H]palmitate (5 µCi/ml) in 0.1% fetal bovine serum. Cells were stimulated with EGF (50 ng/ml) in the presence of 0.3% butanol for 30 min. PLD-catalyzed transphosphatidylation was performed as described previously (5, 13). The lipid phase was extracted and developed by TLC on silica gel 60 plates by using the upper phase of a mixture of ethyl acetate/2,2,4-trimethylpentane/acetic acid (9:5:2) as the solvent. PhosphorImager technology (Molecular Dynamics) was used to determine the amount of labeled phosphatidylbutanol and total lipids.

Reporter Gene Assays-- Reporter plasmids (Stratagene) encoded a luciferase gene whose expression was driven by one of the following cis-acting elements: seven tandem repeats of the AP-1 binding site; four tandem repeats of interferon gamma -activated sequence (GAS), nuclear factor of activated T cells (NFAT), or serum response element (SRE). Cells were grown on 35-mm multiwell plates (Nunc, Naperville, IL) and transiently transfected with 8 µg of total plasmid DNA as described previously (10, 11). Briefly, in each transfection, 0.05 µg of the beta -galactosidase expression plasmid (pCMV-beta Gal; Clontech, Palo Alto, CA) was included to determine the transfection efficiency. At 24 h posttransfection, cells were starved overnight and treated with or without stimuli as described in the figure legends. Cell extracts were prepared, and the activities of beta -galactosidase and luciferase were measured as described previously (10, 11). The luciferase activity in each experiment was divided by the activity of beta -galactosidase to correct for transfection efficiency.

Electrophoretic Mobility Shift Assay-- Nuclear extracts were prepared as described (14). The AP-1 oligonucleotide was labeled with [gamma -32P]ATP and incubated with nuclear extracts for 30 min by using the gel shift assay system kit (Promega, Madison, WI). The specificity of binding was determined by adding homologous or mutated unlabeled synthetic oligonucleotides (Santa Cruz Biotechnology, Inc., Santa Cruz, CA). For gel supershift assays, rabbit affinity-purified antibodies (2 µg) to Jun and Fos families of nuclear factors (Santa Cruz Biotechnology) were incubated for 30 min with nuclear extracts and with synthetic oligonucleotides at room temperature. DNA-protein complexes were resolved on nondenaturing, nonreducing 4% acrylamide gels, and the complexes were visualized by PhosphorImager technology.

    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Identification of ARF4 as an EGFR-interacting Protein by Yeast Two-hybrid Screening-- To identify molecules that act as mediators of EGFR-dependent signaling, we used the cytoplasmic domain of EGFR as bait in a yeast two-hybrid screen. From a human carcinoma cDNA library, 2 × 107 transformants were screened, and 102 positive clones were selected for sequence analysis based on their potential interaction with EGFR. In this GAL4 system, growth of transformed yeast in medium lacking histidine and adenine is completely dependent on the presence of sequences from both ARF4 and EGFR (Fig. 1A). Using the BLAST algorithm and the nucleotide data base at the National Library of Medicine, we found one clone that encoded the small GTPase ARF4.


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Fig. 1.   EGF receptor physically interacts with ARF4 GTPase. A, the yeast strain PJ69-2A was cotransformed with vectors encoding the indicated GAL4 DNA BD and GAL4 AD fusion proteins. Transformed yeast cells were cultured on plates containing selective medium. B, 293T/EGFR cells were transfected with expression vectors encoding wild-type ARF4-HA3 or the ARF4(Q71L)-HA3 or ARF4(T31N)-HA3 mutants. After transfection, cells were starved overnight and then treated with or without EGF for 30 min. Cells were lysed, precipitated with the anti-HA antibody, and electroblotted onto nitrocellulose filters. The top gel shows co-immunoprecipitation of EGFR and ARF4, as detected by Western blot analysis with the anti-EGFR antibody, EGFR (1005) (Santa Cruz Biotechnology). The bottom, control gel shows corresponding samples of each immunocomplex separated by SDS-PAGE, electrotransferred, and analyzed by Western blot with the anti-HA antibody. C, lysates from 293T/EGFR cells were immunoprecipitated with either anti-EGFR or control antibodies before or after EGF stimulation as indicated. Immunocomplexes were electroblotted onto nitrocellulose filters, and precipitated EGFR was detected with the anti-EGFR antibody (top panel). Endogenous ARF4 (second panel) and endogenous ARF1, -3, -5, and -6 (third panel) proteins were detected in these immunocomplexes with antibodies R891 and 1D9, respectively. In the total cell lysates, the presence of endogenous ARF4 (fourth panel) and endogenous ARF1, -3, -5, and -6 (fifth panel) proteins were detected with R891 and 1D9, respectively. D, 293T/EGFR cells were transfected with expression vectors encoding ARF4-HA3 or ARF4(Q71L)-HA3. After transfection, cells were starved overnight followed by stimulation with or without EGF for 10 min. For detecting the tyrosine autophosphorylation of EGFR, cell lysates were immunoprecipitated with anti-EGFR antibody and immunoblotted with anti-PY20 (top panel). EGFR in the immunocomplex (middle panel) and the expression of ARF4-HA3 or ARF4(Q71L)-HA3 in whole cell lysates were detected with anti-EGFR or anti-HA antibodies, respectively. Data are representative of three independent experiments.

To study the interaction between EGFR and ARF4 in mammalian cells, we transfected expression vectors encoding either wild-type or mutant ARF4 with three C-terminal HA epitope tags (ARF4-HA3) into 293T/EGFR cells (Fig. 1B). These transfected cells were treated with or without EGF and later lysed to prepare total cell lysates. From these cell lysates, anti-HA antibody was used to immunoprecipitate HA-tagged ARF4s and other cellular molecules complexed with these ARF4s. The ARF4-HA3 complex was recovered by centrifugation, and the pellets were separated by SDS-PAGE and analyzed by Western blot with an anti-EGFR antibody. As shown in Fig. 1B, EGFR co-purified with wild-type ARF4 only in lysates from EGF-treated cells but not from cells without EGF stimulation. In contrast, EGF treatment was not required for the co-purification of EGFR with the active form of the ARF4 mutant, ARF4(Q71L), which theoretically constitutively binds to GTP (Fig. 1B). The inactive form of ARF4, ARF4(T31N), which constitutively binds to GDP, did not co-immunoprecipitate with EGFR regardless of EGF stimulation of the cells (Fig. 1B). In order to test whether EGFR interacts with endogenous ARF4 or other members of the ARF family, extracts from cells stimulated with or without EGF were immunoprecipitated with anti-EGFR or control antibodies. The resulting immunocomplexes were analyzed by immunoblotting with R891 anti-ARF4 antiserum to detect endogenous ARF4 or with the 1D9 monoclonal antibody to detect the other ARF family members (ARF1, -3, -5, and -6) (7). Fig. 1C shows that ARF4 was present in the immunocomplex derived from EGF-stimulated cells, whereas other ARFs (ARF1, -3, -5, and -6) were not detected in the immunocomplex from EGF-stimulated cells (Fig. 1C). In cells without EGF stimulation, we were unable to detect any endogenous ARFs (ARF1, -3, -4, -5, and -6) that co-immunoprecipitated with EGFR (Fig. 1C). These results suggest that in mammalian cells, EGFR or the EGFR complex preferentially interacts with GTP-bound ARF4 but does not interact with GDP-bound ARF4.

We next tried to determine whether the interaction between EGFR and activated ARF4 as well as the activation of ARF4 could potentially affect the EGFR activation by EGF. We examined tyrosine autophosphorylation of the EGFR signaling domain before or after stimulation of EGF in 293T/EGFR cells expressing wild-type ARF4 or ARF4(Q71L) (Fig. 1D). No difference in the tyrosine autophosphorylation of EGFR was detected in the presence of the wild-type or constitutively active form of ARF, indicating that the association of ARF4 with EGFR and ARF4 activation do not have a detectable effect on EGFR activity before or after EGF induction.

EGF Activates the Binding of GTPgamma S to ARF4 and Induces the Translocation of ARF4 Protein to Cell Membranes-- After we demonstrated that the affinity between ARF4 and EGFR is induced by EGF treatment and that association of ARF4 with GTP is critical for this EGF-induced interaction of EGFR and ARF4, we next examined whether ARF4 translocates to cell membranes and colocalizes with EGFR after EGF stimulation. Before and after EGF induction, the subcellular localization of ARF4-HA3 and EGFR in 293T/EGFR cells was visualized by immunofluorescence microscopy (Fig. 2). Without the addition of EGF, cellular AFR4 was mainly localized in the cytosol, whereas, after EGF induction, cells expressing ARF4 formed membrane ruffles and ARF4 together with EGFR became concentrated in the ruffles. This result suggests that, after EGF induction, ARF4 translocates to membrane ruffles and colocalizes with EGFR.


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Fig. 2.   Colocalization of ARF4 and EGFR after EGF induction. 293T/EGFR cells were transiently transfected with the ARF4-HA3 expression vector. After transfection, cells were starved overnight and then treated with or without EGF (100 ng/ml) at 37 °C for 10 min as indicated. The cells were processed and immunostained with the anti-EGFR antibody to detect the localization of cellular EGFR (left panels, red fluorescence) or anti-HA antibodies to detect the localization of ARF4-HA3 (middle panels, green fluorescence). The merge of red and green fluorescence is shown in the right panels (yellow color).

Next, we examined whether EGF-dependent cell activation would enhance the GTP binding of ARF4. The purified recombinant ARF4 protein was separately incubated with membranes prepared from 293T/EGFR or 293T cells together with GTPgamma S and treated with or without EGF. The amount of GTPgamma S binding to the ARF4 protein was analyzed by a reconstitution assay as previously described (5). Briefly, cell membranes were prepared from 293/EGFR or 293 cells followed by incubation with EGF and/or recombinant ARF4 in the presence of GTPgamma S. Protein-bound GTPgamma S was separated by filtration through nitrocellulose filters and was quantitated by scintillation counting. In comparison with the GTPgamma S binding to the 293T/EGFR cell membranes alone, no significant enhancement of GTPgamma S binding to cell membranes occurred by incorporating either ARF4 or EGF proteins in these assays (Fig. 3A). Conversely, treating this membrane preparation in the presence of both ARF4 and EGF notably increased the level of GTPgamma S association with ARF4 (Fig. 3A), indicating that EGF treatment of membranes boosted the binding of GTPgamma to ARF4. In similar experiments, we used membranes obtained from 293T cells, in which EGFR expression is undetectable. Fig. 3B shows that with these EGFR-deficient membranes, there was no increase of GTPgamma S binding to ARF4, neither by adding ARF4 nor by adding ARF4 and EGF. These results demonstrate that EGF enhances the binding of GTPgamma S to ARF4.


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Fig. 3.   EGF enhances the GTPgamma S binding of ARF and the association between ARF4- and EGFR-enriched cellular membranes. Membranes (Mem) of 293/EGFR (A) or 293T (B) cells treated with or without EGF were incubated with ARF4 protein for 30 min in the presence of [35S]GTPgamma . As negative controls, membranes were boiled at 100 °C for 5 min to denature membrane proteins. Protein-bound nucleotides were separated by filtration through nitrocellulose filters. The amount of bound nucleotide was determined by liquid scintillation counting of the material retained on nitrocellulose filters. Experiments were repeated at least three times. Samples were analyzed statistically by analysis of variance. C, 293T/EGFR cells were transfected with the expression plasmid encoding ARF4-HA3. After serum starvation, 293T/EGFR cells were gently scraped, resuspended in PBS, and permeabilized with digitonin (Dig; 8 µM). GTPgamma S (100 µM) and EGF (100 ng/ml) were included in the permeabilization buffer for the indicated samples. Treated cells were centrifuged, and the resulting pellets and supernatants were separated by SDS-PAGE and analyzed by immunoblot with the anti-HA antibody. The control sample shows results from cells treated with culture medium only, without digitonin. On Western blots, the relative densities of each ARF4 band in C were measured by using the Personal Densitometer SI (Molecular Dynamics). The density of the ARF4 band in digitonin-treated cell pellets was set arbitrarily as 1.

We then examined whether the active GTP-bound form of ARF4 proteins attaches to EGFR-enriched membranes and whether the inactive GDP-bound form of ARF4 remains cytosolic. ARF4 with three C-terminal HA tags (ARF4-HA3) was expressed in 293T/EGFR cells. After serum starvation, cells were collected and incubated with GTPgamma S in the presence or absence of EGF. These cells were then treated with digitonin, a detergent that permeabilizes cell membranes and allows cytosolic ARF4-HA3 to leak out of the cells. The cytosolic and membrane-containing cell pellet fractions of these cells were separated by SDS-PAGE and analyzed by Western blot with an anti-HA antibody to examine the distribution of ARF4-HA3 between these two fractions. The digitonin-treated cells released most of their ARF4-HA3 into the supernatant, indicating that most ARF4-HA3 proteins were cytosolic, whereas without digitonin treatment, ARF4-HA3 remained inside the cells (Fig. 3C). In the presence of either GTPgamma S or EGF, digitonin-treated cells only partially released ARF4-HA3 into supernatant (Fig. 3C). However, when these cells were treated with EGF in combination with GTPgamma S, almost all ARF4-HA3 was retained in the cell membrane-containing cell pellet fraction. These data, together with the EGF-induced ARF4 translocation data shown in Fig. 2, indicate that the activation of ARF4 either by EGF or by association with GTPgamma S induces the translocation of ARF4 from the cytosol to EGFR-enriched cell membranes.

ARF4 Mediates EGF-induced Activation of PLD2-- Previous studies have shown that agonist-induced ARF activation and its consequent translocation to cell membranes stimulate PLD activity (13, 15, 16). To investigate whether EGF-induced ARF4 activation is able to stimulate PLD activity in cells, we transiently co-expressed PLD1 or PLD2 together with ARF4 or its mutants in 293T/EGFR cells, followed by EGF stimulation of particular samples. Activation of cellular PLD was determined by the unique ability of PLD to produce, in the presence of butanol, phosphatidylbutanol, which cannot be further metabolized. In cells overexpressing PLD2 and ARF4, PLD activity was dramatically stimulated by EGF treatment (Fig. 4A). However, in cells overexpressing PLD1 and ARF4, this EGF-induced up-regulation of PLD activity was not observed (Fig. 4B). In addition, overexpressing ARF4(Q71L), the dominant active form of ARF4, constitutively stimulated the activity of PLD2 but did not have the same effect on PLD1 (Fig. 4, A and B). These data suggest that ARF4 mediates EGF-induced cellular activation of PLD2 but does not mediate activation of PLD1. As a positive control in these experiments, we used the small GTPase RalA, which mediates EGF-induced PLD1 activity and, to a lesser extent, PLD2 activity (17) (Fig. 4, A and B).


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Fig. 4.   ARF4 mediates EGF-induced activation of PLD2 but does not mediate EGF-induced activation of PLD1. 293T/EGFR cells (2 × 105) were cotransfected transiently with expression plasmids encoding PLD2 (A) or PLD1 (B) along with expression plasmids encoding ARF4, ARF4(Q71L), ARF4(T31N), or RalA as indicated. After transfection, cells were starved overnight and then treated with or without EGF for 15 min. The efficiency of transfection was monitored by cotransfecting cells with pEGFP-N1 and ARF4, ARF4(Q71L), ARF4(T31N), or RalA expression plasmids. The percentage of transfected cells was estimated 48 h after transfection by comparing the number of fluorescent cells to the total number of cells in the same field. The transfection efficiency for 293T/EGFR was maintained at 70-80%, and only plates with this range of efficiency were used. PLD activity was measured by the accumulation of phosphatidylbutanol (PtdBtd) relative to total lipids. Error bars represent the S.D. of three independent experiments.

ARF4 GTPase Regulates Transcriptional Activity of AP-1 through Activation of PLD2-- PLD activity, in cooperation with EGFR, has been reported to be involved in the transformation of cells (17). One of the major causes of EGFR-dependent cell transformation is the altered expression of specific target genes that results from changing the activities of certain transcriptional factors by unrestrained signaling effectors. The role of PLD2 in the EGF-mediated modulation of gene expression through transcriptional activation has not been thoroughly examined. We tested whether ARF4-mediated PLD2 activation regulates gene transcription through specific enhancer elements, such as AP-1, interferon GAS, NFAT, or SRE. For these experiments, we used expression plasmids encoding the luciferase gene, driven by a basic promoter element (TATA box) joined to tandem repeats of AP-1, GAS, NFAT, or SRE binding elements. These plasmids were individually transfected into 293T/EGFR cells. Expression of activated PLD2 significantly induced luciferase expression driven by the promoter containing AP-1; in contrast, luciferase expression was not induced by promoters containing GAS, NFAT, and SRE binding sites (Fig. 5A). These data suggest that PLD2 activation stimulated by the active form of ARF can enhance AP-1 activity.


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Fig. 5.   ARF4 GTPase enhances transcriptional activity of AP-1 through activation of PLD2. A, 293T/EGFR cells were transfected with the indicated PLD2 and ARF4 expression vectors together with the luciferase reporter gene driven by a minimal promoter containing the cis-acting element of AP-1, GAS, NFAT, or SRE. The luciferase activities were normalized against 293T/EGFR cells transfected with each cis-reporter plasmid alone, whose value was taken as 1. Bars, S.E. of average values from three independent experiments performed in duplicate. 293T/EGFR cells were transfected with the AP-1 (B) or SRE-dependent (C) luciferase reporter plasmid, with or without ARF4(T31N), as indicated. After serum starvation, cells were treated with or without EGF for 10 h, and the luciferase activities were normalized against cells transfected with the AP-1-Luc (B) or SRE-Luc (C) plasmid alone without EGF stimulation, whose value was taken as 1. Bars represent the S.E. of average values from three independent experiments performed in duplicate. In each transfection, 0.05 µg of the beta -galactosidase expression plasmid (pCMV-beta Gal) was included to determine the transfection efficiency. The luciferase activity in each experiment was divided by the activity of beta -galactosidase to correct for transfection efficiency.

We further tested whether this ARF4-mediated PLD2 activation is involved in EGF-induced cellular AP-1 activation. 293T/EGFR cells were transiently transfected with the AP-1- or SRE-driven luciferase reporter constructs and, in some cases, cotransfected with the expression vector encoding ARF4(T31N), followed by EGF treatment (Fig. 5B). EGF induced AP-1-dependent reporter gene expression more than 3-fold, and this induction of luciferase expression was inhibited considerably by dominant negative ARF4(T31N). In contrast, SRE-dependent reporter gene expression stimulated by EGF was not blocked by ARF4(T31N) (Fig. 5C).

To further confirm and characterize the AP-1 activation by ARF4-mediated PLD2 activation, we used nuclear extracts generated from cells transfected with the combination of expression plasmids as indicated in Fig. 5 for electrophoretic mobility shift assay experiments, and the resultant nuclear extracts were incubated with radiolabeled oligonucleotides containing AP-1 sequences. Binding studies revealed that the AP-1/nuclear protein complex increased dramatically in cells containing activated PLD2 due to the co-expression of the ARF4 active form, ARF4(Q71L) (Fig. 6A). Unlabeled homologous AP-1 oligonucleotides prevented the binding of the radiolabeled AP-1 sequences to nuclear proteins, whereas mutated AP-1 oligonucleotides did not prevent this binding (Fig. 6A). In addition, to examine the individual components within the AP-1-nuclear protein binding complex, we included antibodies against c-Jun or c-Fos in some of these electrophoretic mobility shift assay experiments (Fig. 6B). We found that these antibodies significantly up-shifted the binding of nuclear proteins from cells containing activated PLD2 to the AP-1 consensus sequence, suggesting the presence of c-Jun and c-Fos in these DNA-protein complexes (Fig. 6B). In 293T/EGFR cells, EGF induces the binding of nuclear proteins to AP-1 (Fig. 6C). We tested whether ARF4 activity is required for EGF-dependent AP-1 activation. We found that the cellular expression of dominant negative forms of ARF4, ARF4(T31N), dramatically reduced this EGF-mediated binding of nuclear proteins to AP-1 oligonucleotides (Fig. 6C), suggesting a critical role of ARF4 activity in EGF-induced AP-1 activation. Taken together, these results suggest an important function of both ARF4 and PLD2 in regulating the transcriptional activity of AP-1 in the EGF-induced cell activation.


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Fig. 6.   EGF-induced ARF4/PLD2 activation enhances the binding of nuclear proteins to AP-1 sequences. 293T/EGFR cells were transfected with different combinations of expression vectors as indicated: none, PLD2, and PLD2 plus ARF4(Q71L). Nuclear extracts prepared from these transfected cells were incubated with [gamma -32P]oligonucleotides. A, incubations were performed in the absence or presence of a 100-fold excess of unlabeled wild-type or mutated oligonucleotides as noted. The arrow indicates the specific DNA-protein complex. B, incubations were performed in the absence (None) or presence of control nonspecific antibodies (NS) or with antibodies specific to the c-Jun (c-Jun (D)) or to c-Fos (c-Fos (K-25)) families of nuclear proteins (Santa Cruz Biotechnology). C, 293T/EGFR cells were transiently transfected either with an empty expression vector or vector encoding ARF4(T31N). After transfection, cells were starved overnight followed by stimulation with or without EGF (100 ng/ml) for 10 min. Nuclear extracts were prepared and incubated with labeled oligonucleotides alone or together with a 100-fold excess of unlabeled wild-type or mutated oligonucleotides.

Mitogen-activated protein (MAP) kinases have been implicated in the regulation of AP-1 activity (18, 19). To explore the possible involvement of two MAP kinase pathways, BMK1/ERK5 and ERK1/2, in mediating PLD2-induced AP-1 activation, we transfected expression vectors encoding ARF(Q71L) and PLD2 into 293T/EGFR cells and examined the activity of endogenous BMK1/ERK5 and ERK1/2. We found that the activation of PLD2 by ARF4(Q71L) had no detectable effect on endogenous BMK1/ERK5 and ERK1/2 activities (Fig. 7). MEK5(D) and MEK1(E), dominant active forms of MEK5 and MEK1, are known to specifically activate BMK1/ERK5 and ERK1/2, respectively. When MEK5(D) or MEK1(E) were expressed in 293T/EGFR cells, the endogenous BMK1/ERK5 or ERK1/2 was activated correspondingly (Fig. 7). These results suggest that these two MAP kinase cascades are not critically involved in AP-1 activation by the ARF4/PLD2 pathway.


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Fig. 7.   ARF4-dependent PLD2 activation does not up-regulate activities of BMK1/ERK5 and ERK1/2 MAP kinases. 293T/EGFR cells were transiently transfected with expression vectors encoding ARF4(Q71L), PLD2, MEK5(D), or MEK1(E), and the activity of endogenous BMK1/ERK5 and ERK1/2 was determined after 48 h. The phosphorylation and consequent activation of endogenous BMK1 resulted in a shift in its electrophoretic mobility, detected by Western blot analysis with the anti-BMK1 antibody (top panel) (12). Activation of endogenous ERK1/2 was measured in cell lysates by a phospho-specific anti-ERK1/2 antibody (middle panel) and endogenous ERK1/2 was detected by an anti-ERK1/2 antibody (bottom panel). The transfection efficiency for 293T/EGFR was maintained at 70-80% with the pEGFP-N1 plasmid as described in the legend to Fig. 4, and only plates with this range of efficiency were used.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In this study, we have identified ARF4 as an intermediate molecule that interacts with EGFR and have shown that EGFR-mediated ARF4 activation specifically up-regulates cellular PLD2 but does not up-regulate PLD1, activity. Moreover, we have demonstrated that this ARF4-dependent PLD2 activation significantly enhances the transcriptional activity of AP-1. EGFR is known to cooperate with PLD in cellular transformation, yet the molecular mechanism of this oncogenic process is unknown. One possible route, as indicated by our findings, is via the dramatic enhancement of the activity of the AP-1 oncoprotein, resulting from EGFR-dependent PLD activation.

ARFs are usually modified by myristoylation at Gly2 through the action of N-myristoyltransferase (20). Nevertheless, Kanoh et al. (21) have shown that a mutant form of ARF3, which is mutated at Gly2 to eliminate myristoylation, does not abolish its interaction with arfaptin 1. In our yeast two-hybrid analysis (Fig. 1A), affinity between the EGFR cytoplasmic domain and ARF4 does not seem to require N-terminal myristoylation. In yeast two-hybrid-based assay, the ARF4 fusion protein that we used contained an N-terminal GAL4-activating domain, which should have prohibited the ARF4 part of this GAL4-AD/ARF4 fusion protein from being modified by N-myristoyltransferase, an enzyme that can act only at the N-terminal end of a protein (22). Without its N-terminal myristoylation, ARF4 appears to have some affinity with the cytoplasmic domain of EGFR; however, drawing any conclusion is difficult without obtaining additional information about the N-terminal modification of GAL4/ARF4 fusion proteins in yeast. More detailed studies are needed to decipher the contribution of N-terminal myristoylation of ARF4 in its binding to the cytoplasmic domain of activated EGFR.

In general, ARF proteins are involved with vesicle transport within the Golgi complex, between the endoplasmic reticulum and Golgi complex (23), with endosome fusion (24), and with several other processes related to intracellular membrane transport. ARF proteins, with the exception of ARF6, are found either dispersed in the cytosol or associated with Golgi membranes (25); ARF6 is permanently bound to plasma membranes. Our discovery indicates that the ARF4 protein is activated by EGFR-mediated cellular activation and is simultaneously translocated from the cytosol to the cellular membrane. Similarly, ARF1 is known to be activated and translocated to the cell membrane by activation of another receptor tyrosine kinase, the insulin receptor (5). Since ARF1 and ARF4 belong to class I and II ARFs, classes that appear to be similar in both their cellular localization and functions, it is not surprising that both ARF1 and ARF4 are activated by receptor tyrosine kinase-mediated cellular activation and translocated to cellular membranes. However, it would be interesting to know whether the other members of class I and II ARFs behave similarly in receptor tyrosine kinase-dependent stimulation of cells.

PLD, consisting of PLD1 and PLD2 isoforms, hydrolyzes phosphatidylcholine to choline and to the second messenger, phosphatidic acid, which can serve as a signal transducer. PLD2 is a 106-kDa protein that shares 50-55% homology with PLD1 but lacks the 116-amino acid loop region following the first HKD motif, a highly conserved catalytic motif (HXKX4D) that is essential for the enzymatic activity of phosphatidyltransferase (26). PLD2 localizes primarily to plasma membranes, in contrast to PLD1, which localizes solely to perinuclear regions (the endoplasmic reticulum, Golgi apparatus, and late endosomes) (27). In comparison with PLD1, the membrane localization of PLD2 makes it a logical mediator for delivering signals generated from receptors that reside in the cellular membrane. Indeed, other than mediating signaling from activated EGFR, as we have demonstrated, PLD2 can also relay intracellular signals descended from activation of the insulin receptor.

AP-1 activity is modulated by a variety of dimers that are composed of members of the Fos, Jun, and ATF families (28). Whereas the Fos proteins (c-Fos, FosB, Fra-1, and Fra-2) can only form heterodimers with members of the Jun family, the Jun proteins (c-Jun, JunB, and JunD) can form both homodimers and heterodimers with Fos members to form transcriptionally active complexes. Moreover, AP-1 activity has been implicated in many biological processes, including cell differentiation, proliferation, and oncogenic transformation (29-31). The MAP kinase pathways regulate both the amounts and transactivating capacities of the component Fos, Jun, and ATF proteins of AP-1 in a stimulus-specific manner. For instance, treatment of HeLa cells with platelet-derived growth factor, serum, or phorbol esters predominantly activates the extracellular signal-regulated kinase (ERK) members of the MAP kinase family, leading to strong stimulation of Jun and Fos activity. On the other hand, treatment with stress-inducing stimuli, such as ultraviolet light, activates the c-Jun N-terminal kinase/stress-activated protein kinase members of the MAP kinase family, which preferentially enhance Jun and ATF activity via phosphorylation of c-Jun serines 63 and 73 and ATF2 threonines 69 and 71, which are located in their respective transactivation domains (32). In contrast, activation of protein kinase A by cAMP strongly enhances only de novo synthesis of JunB and c-Fos (33). Here, we show that AP-1 activity is up-regulated by EGF-induced PLD2 activation (Fig. 5). Still, the intermediate signaling pathways by which PLD2 induces the activation of AP-1 are presently unknown. We have explored the possible involvement of two MAP kinase pathways, ERK1/2 and BMK1/ERK5, in mediating PLD2-induced AP-1 activation and have found that the ARF4-dependent activation of PLD2 has no effect on endogenous BMK1/ERK5 and ERK1/2 activities (Fig. 7), indicating that these two kinase cascades have no involvement in AP-1 activation by the ARF4/PLD2 pathway. We are currently evaluating other signaling pathways to identify the molecular mechanisms responsible for mediating PLD2-dependent AP-1 activation.

    FOOTNOTES

* This work was supported by National Institutes of Health Grants CA079871 and CA095353 and a grant from the Department of Defense Prostate Cancer Research Program.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.

To whom correspondence should be addressed. E-mail: jdlee@scripps.edu.

Published, JBC Papers in Press, November 21, 2002, DOI 10.1074/jbc.M205819200

    ABBREVIATIONS

The abbreviations used are: EGFR, epidermal growth factor receptor; EGF, epidermal growth factor; PLD, phospholipase D; AP-1, activated protein-1; ARF, ADP-ribosylation factor; AD, activation domain; BD, binding domain; GAS, interferon-gamma activation site; NFAT, nuclear factor of activated T cell; HA, hemagglutinin; PBS, phosphate-buffered saline; SRE, sterol-regulatory element; MAP, mitogen-activated protein; ERK, extracellular signal-regulated kinase; GTPgamma S, guanosine 5'-3-O-(thio)triphosphate.

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RESULTS
DISCUSSION
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