From the
Institute of Molecular and Cell Biology, 30 Medical Drive, Singapore
117609 and the Department of Medicine,
National University of Singapore, Singapore 119074, Republic of
Singapore
Received for publication, March 12, 2003 , and in revised form, May 2, 2003.
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ABSTRACT |
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INTRODUCTION |
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One common mechanism utilized by small GTPases to regulate cellular function is to cycle between the inactive GDP-bound state and the active GTP-bound state. Guanine nucleotide exchange factors (GEFs) facilitate GDP dissociation and allow the more abundant GTP to rebind, while GTPase-activating proteins (GAPs) accelerate GTP hydrolysis to complete the cycle (1, 7). C3G is a Rap-specific GEF since it predominantly catalyzes the guanine nucleotide exchange reaction for Rap1 and Rap2 (10, 11). C3G was originally identified as a major protein bound to the SH3 domain of c-Crk (12). There are three proline-rich sequences that bind to the SH3 domain of c-Crk in the central region of C3G and one C-terminal CDC25 homology domain catalyzing the GEF reaction of Rap (13). The function of the C3G N terminus remains unknown but recent studies have reported the association of p130cas to this region (14). C3G is activated by c-Crk-mediated membrane recruitment. Two isoforms of c-Crk protein are generated by alternative mRNA splicing. The larger form is CrkII, containing one SH2 domain and two SH3 domains, while the smaller form is CrkI, which lacks the C-terminal SH3 domain and one negative regulatory tyrosine residue compared with CrkII. CrkII is more abundant than CrkI in normal cells; therefore, CrkII is the major adaptor for C3G (15). A number of growth factors and cytokines stimulate the recruitment of the Crk-C3G complex to the membrane where tyrosine kinases are located such that C3G tyrosine residue 504 is phosphorylated with a resultant increase in its GEF activity (16, 17).
GH is the primary regulator of postnatal somatic growth and metabolism (18, 19). It utilizes special groups of signaling molecules to regulate the transcription of specific genes required for the above processes. These signaling molecules include: 1) receptor-tyrosine kinases (EGF receptor) (20) and non-receptor-tyrosine kinases (JAK2, Ref. 3; c-Src; c-Fyn, Ref. 21; and FAK, Ref. 22), although in the case of the EGF receptor it may be used simply as an adaptor protein; 2) members of the MAP kinase family including p44/42 MAP kinase (23), p38 MAP kinase (24), and JNK/SAPK (21) and their respective downstream effectors; 3) members of the insulin receptor substrate (IRS) group including IRS-1, -2, and -3, which may act as docking proteins for further activation of signaling molecules including phosphatidylinositol 3-kinase (25); 4) small Ras-like GTPases (26); and 5) STAT family members including STATs 1, 3, 5a, and 5b (27, 28), which constitute one group of signaling molecules involved in transcriptional regulation by GH. Although JAK2 is postulated to be required for GH signal transduction, our group has recently identified a JAK2-independent pathway regulating GH-stimulated p44/42 MAP kinase activity (29). GH stimulated the formation of GTP-bound RalA and subsequent phospholipase D activation, required for the activation of p44/42 MAP kinase by GH in a c-Src-dependent manner.
Here we have demonstrated that cellular stimulation with GH results in the activation of both Rap1 and Rap2 in NIH-3T3 cells. The activation of Rap by GH was achieved by the combined JAK2- and c-Src-dependent tyrosine phosphorylation of C3G. GH-stimulated Rap1 activation was utilized to negatively modulate GH-stimulated p44/42 MAP kinase activity and subsequent Elk-1-mediated transcription through inhibition of RalA activity. Concomitantly, GH stimulated C3G-dependent activation of Rap1-enhanced JNK/SAPK activity and subsequent c-Jun-mediated transcription in response to GH. Rap1 is therefore a GH effector molecule activated in a JAK2-independent manner.
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EXPERIMENTAL PROCEDURES |
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pET15b-GST-RalGDS-RBD construct encoding the 97 amino acids spanning RBD of RalGDS, pGEX4T3-GST-RalBD construct for GST-RLIP-RBD containing amino acids 397518 of human RLIP76 and pGEX2T-RBD construct for GST-Raf1-RBD containing amino acids 51131 of Raf-1 (8, 30, 31) were the generous gifts of Dr. Johannes L. Bos (Utrecht, Netherlands). The wild-type and dominant-negative Rap1A plasmids were kindly provided by Dr. Alfred Wittinghofer (Dortmund, Germany). The dominant-negative c-Src plasmid was obtained from Dr. Joan S. Brugge (Boston, MA). The dominant-negative JAK2 plasmid was a kind gift of Dr. Olli Silvennoinen (Tampere, Finland). The wild-type CrkII expression vector and the wild-type and mutant form of C3G were generously provided by Dr. Michiyuki Matsuda (Tokyo, Japan). The dominant-negative Ras plasmid was purchased from Upstate Biotechnology. The fusion trans-activator plasmid (pFA-Elk-1) consisting of the DNA binding domain of Gal4 (residues 1147) and the transactivation domain of Elk-1 were purchased from Stratagene (La Jolla, CA). All plasmids were prepared with the plasmid maxiprep kit from Qiagen.
Cell Culture and TreatmentNIH-3T3 cells were grown at 37 °C in 5% CO2 in Dulbecco's modified Eagle's medium containing 10% heat-inactivated fetal bovine serum, 100 units/ml penicillin, 100 µg/ml streptomycin, and 2 mM L-glutamine. Prior to treatment, cells were deprived for 2024 h in medium containing 0.5% fetal bovine serum. Unless otherwise indicated, the concentration of hGH was 50 nM. This concentration of GH is within the physiological range for circulating rodent GH (32).
Rap, Ral, and Ras Activation AssaysSerum-deprived cells were stimulated with hGH as indicated and then lysed on ice for 15 min in Ral buffer (50 mM Tris-HCl, pH 7.5, 200 mM NaCl, 2.5 mM MgCl2, 10% glycerol, 1% Nonidet P-40, 1 mM phenylmethylsulfonyl fluoride, 1 mM Na3VO4, and 1 tablet complete protease inhibitor mixture per 50 ml). After lysis samples were centrifuged at 14,000 x g at 4 °C for 10 min, and the protein concentrations of the lysates were measured. 500 µg of cell lysates were immediately affinity-precipitated at 4 °C for 1 h with 50 µg of GST-RalGDS-RBD or 15 µg of GST-RalBP1-RBD or GST-Raf1-RBD fusion proteins that had been freshly precoupled to glutathioneagarose beads. The precipitates were washed three times with Ral buffer, and the bound proteins were eluted in 20 µl of Laemmli sample buffer. Samples were separated by 12% polyacrylamide SDS-PAGE and detected by Western blot analysis.
ImmunoprecipitationAfter treatment as indicated, cells were lysed at 4 °C for 20 min in 1% Nonidet P-40 lysis buffer (50 mM Tris-HCl, pH 7.4, 1% Nonidet P-40, 150 mM NaCl, 1 mM EDTA, 1 mM NaF, 1 mM phenylmethylsulfonyl fluoride, 1 mM Na3VO4, 1 tablet complete protease inhibitor mixture per 50 ml). Cell lysates were centrifuged at 14,000 x g for 15 min, and the supernatants were precleared by protein A/G plus agarose chromatography. The agarose beads were removed by centrifugation, and then the protein concentrations of the resulting supernatants were determined. For each immunoprecipitation, 5001000 µg of protein was incubated with 48 µg of corresponding antibody for 4 h or overnight at 4 °C. Immunocomplexes were collected by incubating with 40 µl of protein A/G plus agarose for 1 h or overnight. Immunoprecipitates were washed three times with IP buffer (10 mM Tris-HCl, pH 7.4, 1% Triton X-100, 1% Nonidet P-40, 150 mM NaCl, 1 mM EDTA, pH 8.0, 1 mM EGTA, pH 8.0, 1 mM phenylmethylsulfonyl fluoride, 1 mM Na3VO4, 1 tablet complete protease inhibitor mixture per 50 ml). The bound proteins were eluted in Laemmli sample buffer and then resolved by 810% SDS-PAGE.
Western Blot AnalysisAfter SDS-PAGE, proteins were transferred to nitrocellulose membranes. The membranes were blocked with 5% nonfat dry milk in phosphate-buffered saline with 0.1% Tween-20 (PBST) for 1 h at 22 °C. Blots were then immunolabeled with the desired antibodies for 1 h at 22 °C. For reblotting, membranes were stripped at 50 °C for 30 min in the solution containing 62.5 mM Tris-HCl, pH 6.7, 2% SDS, and 0.7% mercaptoethanol. Blots were then washed for 30 min with several changes of PBST at 22 °C. Efficacy of stripping was determined by re-exposure of the membranes to ECL. Thereafter, membranes were reblocked and immunolabeled as described above.
p44/42 MAP Kinase Assayp44/42 MAPK kinase assays were performed according to the manufacturer's instructions. Briefly, cells were lysed at 4 °C in lysis buffer provided, and the cell extract containing 200 µg of protein per sample was incubated for 4 h or overnight with 15 µl of immobilized phosphospecific p44/42 MAP kinase (Tyr-202/Tyr-204) monoclonal antibody. The pellets were washed twice with 500 µl of lysis buffer and twice with 500 µl of kinase assay buffer provided. The kinase reactions were performed in the presence of 2 µg of Elk-1 fusion protein and 200 µM ATP at 30 °C for 30 min. Elk-1 phosphorylation was detected by use of a specific phospho-Elk1 (Ser-383) antibody.
SAPK/JNK AssaySAPK/JNK assays were performed according to the manufacturer's instructions. Briefly, cells were lysed at 4 °C in lysis buffer provided and the cell extract containing 250 µg of total protein per sample was incubated overnight at 4 °C with 20 µl of c-Jun fusion protein beads. The pellets were washed twice with 500 µl of lysis buffer and twice with 500 µl of kinase assay buffer provided. The kinase assay was performed in the presence of 100 µM ATP at 30 °C for 30 min. c-Jun phosphorylation was detected by use of a specific phospho-c-Jun (Ser-63) antibody.
Elk-1 Reporter AssayCells were cultured to 6080% confluence in 6-well plates and transfected with 0.4 µg of the reporter plasmid pFR-Luc, 8 ng of the fusion trans-activator plasmid pFA-Elk1, and 1 µg of the expression plasmid as indicated or empty vector in each well. 25 µl of Effectene was used for each microgram of DNA according to the manufacturer's instructions. DNA-lipid complex was diluted in medium containing 2% fetal bovine serum for 1620 h. 50 nM hGH was added for an additional 24 h. The cells were washed in cold phosphate-buffered saline twice and then lysed with 150 µl of 1x lysis buffer (25 mM Tris-phosphate, pH 7.8, 2 mM EDTA, 2 mM EDTA, 2 mM dithiothreitol, 10% glycerol, 1% Triton X-100) for 20 min, and supernatant was collected by centrifugation at 14,000 x g for 15 min. The luciferase activity was detected and normalized by protein content.
c-Jun Reporter AssayCells were cultured to 6080% confluence in 6-well plates and transfected with 0.2 µg of the reporter plasmid pFR-Luc, 4 ng of the fusion trans-activator plasmid pFA-cJun, and 1 µg of the expression plasmid as indicated or empty vector in each well. 25 µl of Effectene was used for each microgram of DNA according to the manufacturer's instructions. DNA-lipid complex was diluted in medium containing 5% fetal bovine serum for 12 h. 50 nM hGH was added for an additional 18 h. The cells were washed in cold phosphate-buffered saline twice and then lysed with 150 µl of 1x lysis buffer (25 mM Tris-phosphate, pH 7.8, 2 mM EDTA, 2 mM EDTA, 2 mM dithiothreitol, 10% glycerol, 1% Triton X-100) for 20 min, and supernatant was collected by centrifugation at 14,000 x g for 15 min. The luciferase activity was detected and normalized by protein content.
Statistical Analysis and Presentation of DataAll experiments were performed at least three times. Numerical data were expressed as mean ± S.D. Data were analyzed using the two-tailed t test or analysis of variance.
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RESULTS |
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GH-stimulated Activation of Rap1 and Rap2 Are Cell Density-dependentDuring the course of experimentation, an effect of cell density in monolayer culture on the ability of GH to stimulate Rap1 and Rap2 activity was noticed. We therefore compared Rap activity under conditions of increasing cell density that approximated 40, 70, and 100% cell confluence, respectively. A decrease of both basal and GH-stimulated Rap1 and Rap2 activity was observed with increasing cell density. Thus, GH stimulation of NIH-3T3 cells at 100% confluence failed to stimulate the formation of GTP-bound Rap1 and only minimal activation of Rap2 by GH under these conditions was observed (Fig. 2, A and C). This effect of cell density on the ability of GH to stimulate the formation of Rap1-GTP and Rap2-GTP was not due to decreased Rap protein as the total cellular level of both Rap1 and Rap2 was equivalent at different cell densities (Fig. 2, B and D). GH activation of Rap1 and Rap2 was therefore cell density-dependent.
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Full Activation of Rap1 and Rap2 by GH Requires both JAK2 and c-SrcGH activates both JAK2 and c-Src kinases independent of the other (29). We have previously demonstrated that two other small Ras-like GTPases, RalA and RalB, require the activity of both c-Src and JAK2 to be fully activated by GH (29). We therefore next examined the requirement of JAK2 and c-Src for GH-stimulated activation of Rap1 and Rap2. Upon forced expression of the JAK2 kinase-deficient mutant (K882E) (34), both the basal and GH-stimulated formation of Rap1-GTP and Rap2-GTP were diminished, but GH stimulation of cells still resulted in increased Rap1 and Rap2 activity (Fig. 3, A and C). We have previously demonstrated the efficacy of forced expression of JAK2-K882E to prevent GH-stimulated activation of JAK2- and JAK2-dependent signal transduction (29). Forced expression of the c-Src kinase inactive mutant (K295R/Y527F) (35) also abrogated the ability of GH to stimulate the formation of GTP bound Rap1 and Rap2 (Fig. 3, A and C) to a greater extent than that observed with JAK2-K882E. Co-transfection of cDNA for both JAK2-K882E and c-Src-K295R/Y527F completely prevented the ability of GH to stimulate the formation of GTP-bound Rap1 and Rap2 (Fig. 3, A and C). Forced expression of either JAK2-K882E or c-Src-K295R/Y527F or both did not alter the total cellular level of Rap1 or Rap2 (Fig. 3, B and D). Forced expression of the kinase-deficient JAK2 and c-Src mutants were verified by Western blot analysis (Fig. 3, E and F). Therefore, we conclude that although the combined activities of both JAK2 and c-Src kinases are required for full activation of Rap1 and Rap2 by GH, c-Src is predominantly utilized by GH to activate these molecules.
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Overexpression of CrkII and C3G Enhances GH-stimulated Rap1 and Rap2 ActivityWe have previously demonstrated that GH stimulates the formation of a multiprotein signaling complex centered around CrkII (21). CrkII and C3G are constitutively associated within this complex although hGH stimulation of cells results in tyrosine phosphorylation of CrkII (21). CrkII is an adaptor protein and has been reported to recruit C3G to the vicinity of kinase molecules (17). C3G is a Rap-specific GEF that accelerates the replacement of GDP by GTP so as to increase Rap activity (11). We therefore proceeded to examine the involvement of CrkII and C3G in the GH stimulated formation of GTP-bound Rap1 and Rap2. Forced expression of CrkII enhanced the ability of GH to activate both Rap1 and Rap2 (Fig. 4, A and C). Forced expression of C3G, or CrkII together with C3G, resulted in a dramatic enhancement of GH-stimulated formation of GTP-bound Rap1 and Rap2 (Fig. 4, A and C). Forced expression of CrkII and C3G was verified by Western blot analysis (Fig. 4, E and F) and expression of these proteins did not alter the total cellular level of either Rap1 or Rap2 (Fig. 4, B and D). Thus, GH activation of Rap1 and Rap2 is CrkII-C3G-dependent.
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C3G Tyrosine Phosphorylation Is Required for GH-stimulated Rap1 and Rap2 ActivationTyrosine phosphorylation of C3G has been reported to be required for the GEF activity necessary for Rap1 activation (17). We therefore first examined whether GH stimulation of NIH-3T3 cells resulted in tyrosine phosphorylation of C3G. As observed in Fig. 5A, GH indeed stimulated the tyrosine phosphorylation of C3G. GH-stimulated tyrosine phosphorylation of C3G was first observed at 1 min, persisted to 15 min, and then declined at 3060 min after stimulation with GH. Equivalent loading of immunoprecipitated C3G was demonstrated by reprobing of the membrane for C3G (Fig. 5B).
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To determine the kinases responsible for hGH-stimulated tyrosine phosphorylation of C3G we utilized the kinase-deficient mutants of both JAK2 (JAK2-K882E) and c-Src (c-Src-K295R/Y527F). Similar to the pattern observed with GH-stimulated formation of GTP-bound Rap1 and Rap2 (above), removal of the activities of both kinases was required for complete prevention of GH-stimulated C3G tyrosine phosphorylation (Fig. 5C). Equivalent loading of immunoprecipitated C3G was demonstrated by reprobing of the membrane for C3G (Fig. 5D). Forced expression of the kinase-deficient mutants of both JAK2 and c-Src was demonstrated by Western blot analysis (Fig. 5, E and F). Thus GH-stimulated tyrosine phosphorylation of C3G required the combined activities of both JAK2 and c-Src.
We next examined whether tyrosine phosphorylation of C3G was required for GH stimulated Rap1 and Rap2 activation. It has been reported that tyrosine 504 of C3G is the critical tyrosine residue required for guanine nucleotide exchange activity for Rap1 (17). To determine if GH-stimulated C3G tyrosine phosphorylation was required for activation of Rap1 and Rap2 we therefore utilized a C3G mutant (C3G-Y504F) in which tyrosine 504 was substituted by phenylalanine (17). As above, forced expression of wild-type C3G enhanced the ability of GH to activate Rap1 and Rap2 whereas forced expression of C3G-Y504F completely prevented the ability of GH to stimulate the formation of GTP-bound Rap1 and Rap2 (Fig. 5, G and I). Forced expression of either wild-type C3G or C3G-Y504F did not alter the total cellular Rap1 or Rap2 (Fig. 5, H and J) and was demonstrated by Western blot analysis (Fig. 5K). GH-stimulated phosphorylation of C3G tyrosine residue 504 is therefore required for GH-stimulated formation of GTP-bound Rap1 and Rap2.
Rap1 Inhibits GH-stimulated p44/42 MAP Kinase Activity and Elk-1-mediated TranscriptionAmong the different Rap1 effectors, p44/42 MAP kinase has been extensively studied (1). Rap1 has been reported to either stimulate or inhibit p44/42 MAP kinase activity depending on the cellular context (1). p44/42 MAP kinase is also activated by GH (23) to exert pleiotropic cellular effects (19) and its mechanism of activation has been extensively studied (3, 26, 29). We therefore first examined the effect of forced expression of Rap1 on the ability of GH to stimulate p44/42 MAP kinase activity. GH stimulation of vector-transfected NIH-3T3 cells resulted in a rapid and prolonged activation of p44/42 MAP kinase activity such that at 60 min after GH stimulation, p44/42 MAP kinase activity was still higher than in the basal state (Fig. 6A). Forced expression of Rap1 did not affect the ability of GH to activate p44/42 MAP kinase but prevented the sustained activation of p44/42 MAP kinase (Fig. 6A). Thus, p44/42 MAP kinase activity was not detectable as early as 30 min after stimulation with GH in the presence of forcibly expressed Rap1. Concordantly, forced expression of dominant-negative Rap1S17N prolonged GH-stimulated p44/42 MAP kinase activity in comparison to vector-transfected control (1Fig. 6D). Thus, markedly less diminution of p44/42 MAP kinase activity was observed at both 30 and 60 min after GH stimulation when Rap1 activation by GH was inhibited.
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Activation of p44/42 MAP kinase by GH subsequently results in Elk-1-mediated transcription (36) and has been suggested to depend on MAP kinase activity, which is sustained after more than 30 min of cell stimulation (37). We therefore examined the effect of forced expression of both wild-type Rap1 and Rap1S17N on the ability of GH to stimulate Elk-1-mediated transcription. Forced expression of wild-type Rap1 completely prevented GH-stimulated Elk-1-mediated transcription that was observed in the vector-transfected control (Fig. 6G). Rap1S17N consistently enhanced the ability of GH to stimulate Elk-1-mediated transcription (Fig. 6G). Rap1 therefore negatively regulates the ability of GH to maintain sustained activation of p44/42 MAP kinase activity and subsequent Elk-1-mediated transcription.
Ras and Rap Are Activated by GH Independent of the Other We have previously demonstrated that activation of two small GTPases by GH, RalA and RalB, is partially Ras-dependent (29). We therefore examined whether the GH-stimulated formation of Rap1 and Rap2 required prior activation of Ras. However, as shown in Fig. 7, A and C, forced expression of either wild-type or dominant-negative mutant of Ras did not alter the ability of GH to stimulate the formation of GTP-bound Rap1 or Rap2. We next examined whether Rap affected the ability of GH to activate Ras. Forced expression of wild-type Rap1 did not alter the ability of GH to stimulate the formation of GTP-bound Ras (Fig. 7F). Concordantly forced expression of Rap1S17N was without effect on GH-stimulated Ras activity (Fig. 7F). Forced expression of Ras and Rap1 proteins was demonstrated by Western blot analysis (Fig. 7, E and H).
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Rap1 Inhibits GH-stimulated Elk-1-mediated Transcription through Inactivation of RalARalGDS, the Rap1 effector, is also a Ral specific GEF (38, 39) providing a potential mechanism for the regulation of Ral activity by Rap1 (40). We have previously demonstrated that GH stimulates the formation of GTP-bound RalA required for full p44/42 MAP kinase activation by GH and subsequent Elk-1-mediated transcription (29). We therefore examined whether Rap1 inhibition of GH-stimulated Elk-1-mediated transcription was via modulation of GH-stimulated RalA activity. GH stimulation of NIH-3T3 cells resulted in robust formation of GTP-bound RalA as previously reported by us (29). Forced expression of wild-type Rap1 dramatically inhibited the ability of GH to stimulate the activation of RalA (Fig. 8A). Concordantly forced expression of the dominant-negative Rap1S17N enhanced the ability of GH to stimulate the formation of GTP-bound Rap1 (Fig. 8A). Forced expression of Rap1 and Rap1S17N was demonstrated by Western blot analysis (Fig. 8C) and did not affect total cellular levels of RalA (Fig. 8B). We next examined the interaction between Rap1 and RalA for the ability of GH to stimulate Elk-1-mediated transcription as an indicator of p44/42 MAP kinase activity. GH-stimulated Elk-1-mediated transcription was inhibited by forced expression of Rap1 and dramatically enhanced by forced expression of RalA (Fig. 8D). Forced expression of Rap1 concommitant with RalA abrogated the ability of RalA to enhance GH-stimulated Elk-1-mediated transcription. Rap1S17N slightly enhanced the fold stimulation by GH of Elk-1-mediated transcription. Dominant-negative RalA completely prevented GH-stimulated Elk-1-mediated transcription in cells transfected either with empty vector or with Rap1S17N (Fig. 8D). Thus, Rap1 influences the ability of GH to activate p44/42 MAP kinase activity and subsequent Elk-1-mediated transcription by modulation of GH-stimulated formation of GTP-bound RalA.
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C3G and Rap1 Are Utilized by CrkII to Enhance GH-stimulated JNK/SAPK Activity and Subsequent c-Jun-mediated TranscriptionWe have previously reported that CrkII served as a molecular switch for the selective activation of JNK/SAPK by GH and concomitant inactivation of GH-stimulated p44/42 MAP kinase (41). We therefore examined whether C3G and Rap1 are required for CrkII enhancement of GH-stimulated JNK/SAPK activity. As demonstrated in Fig. 9A, forced expression of either CrkII or C3G enhanced GH-stimulated JNK/SAPK activity. Forced co-expression of both CrkII and C3G further enhanced both basal and GH-stimulated JNK/SAPK activity (Fig. 9A). Expression of the inactive C3G-Y504F mutant did not affect GH-stimulated JNK/SAPK activity in NIH-3T3 cells. It could, however, prevent the enhanced GH-stimulated JNK/SAPK activity observed upon forced expression of CrkII (Fig. 9A). Forced expression of CrkII, C3G, and C3GY504F was demonstrated by Western blot analysis (Fig. 9, B and C). We next examined the effect of forced expression of CrkII and C3G on the ability of GH to stimulate c-Jun-mediated transcription. GH stimulation of NIH-3T3 cells resulted in minimal stimulation of c-Jun-mediated transcription (Fig. 9D). Forced expression of either CrkII or C3G enhanced the ability of GH to stimulate c-Jun-mediated transcription (Fig. 9D). Concordant with JNK/SAPK activity, forced co-expression of both CrkII and C3G enhanced both basal and GH-stimulated c-Jun-mediated transcription. Again, similar to the effect observed with JNK/SAPK activity, the C3G-Y504F mutant did not affect GH-stimulated c-Jun-mediated transcription per se but did prevent the enhanced GH-stimulated c-Jun-mediated transcription observed upon forced expression of CrkII (Fig. 9D).
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We next examined whether Rap1 is required for CrkII enhancement of GH-stimulated JNK/SAPK activity. As demonstrated in Fig. 9E, forced expression of either CrkII or Rap1 enhanced GH-stimulated JNK/SAPK activity. Forced co-expression of both CrkII and Rap1 dramatically enhanced both basal and GH-stimulated JNK/SAPK activity (Fig. 9E). Expression of the dominant-negative Rap1S17N did not affect GH-stimulated JNK/SAPK activity per se. It could, however, largely prevent the enhanced GH-stimulated JNK/SAPK activity observed upon forced expression of CrkII (Fig. 9E). Forced expression of CrkII, Rap1, and Rap1S17N was demonstrated by Western blot analysis (Fig. 9, F and G). We next examined the effect of forced expression of CrkII and Rap1 on the ability of GH to stimulate c-Jun-mediated transcription. GH stimulation of NIH-3T3 cells resulted in minimal stimulation of c-Junmediated transcription (Fig. 9H). Forced expression of either CrkII or Rap1 enhanced the ability of GH to stimulate c-Junmediated transcription. Forced co-expression of both CrkII and Rap1 resulted in a dramatic enhancement of GH-stimulated c-Jun-mediated transcription (Fig. 9H). Similar to the effect observed with JNK/SAPK activity, the dominant-negative Rap1S17N did not affect GH-stimulated c-Jun-mediated transcription per se but did prevent the enhanced GH-stimulated c-Jun-mediated transcription observed upon forced expression of CrkII (Fig. 9H)
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DISCUSSION |
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It is interesting to note that cell density exerted a significant
inhibitory effect on both basal and GH-stimulated Rap activity. This is
consistent with a previous report demonstrating that basal Rap1 activity is
cell density-dependent (44).
Rap1 has also been demonstrated to be activated upon cell adhesion to ECM and
is implicated in integrin-mediated cell adhesion in various cells in response
to diverse extracellular stimuli
(1). Integrins, the
transmembrane glycoproteins that usually bind cells to ECM, may also bind
cells to cells in a calcium-dependent manner
(45). The involved integrins
are heterodimers composed of both the -subunit and the
2 subunit. Although integrins may participate in
intercellular interaction, most cell-cell adhesions are mediated by cadherin
that is linked with the actin cytoskeleton through
-catenin
(46). Recently, a novel
-catenin-interacting protein with a putative Rap1GEF activity has been
identified (47), suggesting a
role for Rap1 in the regulation of cell-cell contact. Furthermore, the yeast
Rap1 homologue, Bud1, can directly activate Cdc24, an exchange factor for
Cdc42, which is involved in the recruitment of actin cytoskeleton to the bud
site (48). Rap2 has been
demonstrated to bind specifically with actin filaments to interact with
cytoskeletal components (49).
We have also observed a GH-dependent association between Rap1 and actin by
co-immunoprecipitation.2
Proliferation of NIH-3T3 cells is known to be highly sensitive to contact
inhibition (50). In this
regard it is interesting that we have observed that autocrine production of GH
in human mammary carcinoma cells results in disassembly of adherens junctions
and loss of intercellular
contact.3 How this
phenomenon relates to the inability of GH to activate Rap1 in confluent cells
remains to be determined.
We have demonstrated here that full activation of Rap1 and Rap2 by GH requires the combined activity of both JAK2 and c-Src, although c-Src is the predominant kinase utilized by GH for this purpose. We have therefore described another JAK2-independent mechanism by which GH affects cellular function. In addition, our findings have determined that JAK2 and c-Src activate Rap through tyrosine phosphorylation and activation of C3G, a Rap-specific GEF. These results are concordant with our recent observation that GH-stimulated formation of both GTP-bound RalA and RalB also required both c-Src and JAK2 (29). We have previously demonstrated that GH activates JAK2 and c-Src independent of, and parallel to, each other (29). The two kinases obviously converge for joint phosphorylation of C3G required for Rap activation by GH and the relative contribution of each kinase may simply depend on the relative expression of JAK2 or c-Src in a particular cell type. Both JAK and c-Src have previously been demonstrated to be utilized for activation of Rap1 (51, 52). One example of JAK-dependent activation of Rap1 is the requirement of JAK1 and Tyk2 for Rap1 activation in type I IFN signaling (52). Src-dependent Rap1 activation is essential for integrin-mediated cell adhesion and formation of focal adhesion structures (53). The adaptor protein CrkII has been identified to mediate Src-dependent Rap1 activation (54). We have previously demonstrated that CrkII is constitutively associated with C3G (21), and GH-stimulated Rap activation is CrkII-C3G-dependent (this study). CrkII possesses a pivotal role in GH signal transduction (41) and is central to the formation of a large multiprotein signaling complex upon GH stimulation of cells (21). Thus, CrkII may recruit C3G to the vicinity of JAK2 to facilitate C3G tyrosine phosphorylation by JAK2. FAK may act as a bridge between CrkII and JAK2 since GH can stimulate the association of FAK with both JAK2 and CrkII (21, 22). c-Src activated by GH also forms part of the multi-protein complex centered around CrkII (21). Interestingly, an increased association stimulated by GH is also observed between FAK and c-Src (21) and therefore CrkII may facilitate the formation of this triple kinase complex together with C3G. In any case, cellular stimulation with GH results in the tyrosine phosphorylation of C3G. It has been reported that the phosphorylation of tyrosine residue 504 (Tyr-504) in C3G is critical for C3G-dependent Rap1 activation, presumably as phosphorylation of Tyr-504 in C3G represses the negative regulation of C3G activity by its N-terminal domain (17). Consistent with this observation, the C3G-Y504F mutant, in which Tyr-504 is replaced by the nonphosphorylable residue phenylalanine, prevented GH-stimulated formation of GTP-bound Rap. Both JAK2 and c-Src must therefore phosphorylate this same residue to achieve activation of Rap1 by GH. CrkII-C3G-dependent activation of Rap1 therefore constitutes another JAK2-independent pathway utilized by GH.
We have demonstrated here that the forced expression of wild-type Rap1 prevented the prolonged activation of p44/42 MAP kinase activity observed after cellular stimulation with GH. Concordantly, forced expression of the dominant-negative mutant of Rap1 prolonged the activation of p44/42 MAP kinase by GH. Several studies have previously demonstrated that Rap1, or mutants thereof, can inhibit the p44/42 MAP kinase pathway (1). For example, a constitutively active mutant of Rap1 was reported to inhibit LPA or EGF induced p44/42 MAP kinase activity and Ras-p44/42 MAP kinase stimulated IL-2 expression (5557). IL-1-stimulated activation of Rap1 was also observed to repress Ras-mediated activation of p44/42 MAP kinase signaling (43). These observations support a model of Rap function stating that Rap1 is a functional antagonist of Ras activity; originating from the demonstration of Rap1 reversion of the K-ras transformed phenotype in NIH-3T3 cells (6). There are therefore two possible mechanisms for Rap1 to inhibit Ras signaling. First, Ras and Rap1 may possess a regulator and effector relationship in the same pathway. However, it has been demonstrated that Rap1 is not upstream of Ras (57), which is also observed in this study and here we report that GH-stimulated Rap activation is not Ras-dependent. Therefore, a more plausible mechanism is that Ras and Rap1 are involved in distinct pathways while competing for the same effector(s). Due to the striking structural similarity in the effector domain of Rap1 and Ras (58), it has been proposed that Rap1 interferes with Ras signaling pathway by sequestering the Ras substrate Raf-1 kinase. However, although Rap1 binds to Raf-1 in vitro and in vivo (8, 55, 59), there is still no demonstration to date that Rap1 inhibits Raf-1 kinase activity (1). Furthermore, Raf kinase-independent regulation of p44/42 MAP kinase by Rap1 has been identified recently (44). GH-stimulated p44/42 MAP kinase activation has been demonstrated to require both Ras and Raf-1 activity (3). However, we observed no association between Rap1 and Raf-1 in NIH-3T3 cells either in the quiescent or GH-stimulated state.2 We have, however, demonstrated here that Rap1 inhibits GH-stimulated formation of GTP-bound RalA. We have previously reported that forced expression of RalA prolongs GH-stimulated p44/42 MAP kinase activity (29). The inhibition of the GH-stimulated formation of GTP-bound RalA by Rap1 is presumably mediated by RalGDS, a putative effector shared by Ras and Rap1. As a member of the RalGEF family, RalGDS contains RBDs that bind to activated Ras or Rap1 in vitro and in vivo (38). Ras-dependent Ral activation has been demonstrated to be inhibited by Rap1 due to the retention of RalGDS to the compartment where Rap1 is located, instead of being recruited by Ras to the site of Ral (40). Subcellular localization of Rap1 is mainly at cytosol and the perinuclear compartment, different to that of Ras and Ral localized at the plasma membrane. RalGDS is found in the cytosol and can be recruited to plasma membrane by Ras in order to activate Ral (40). It has been reported for some time that co-localization of Ras and Ral on the plasma membrane is necessary for Ral activation in COS cells (60). Furthermore the localization of RalGDS to the plasma membrane is sufficient for Ral activation (40). Both Ras and Rap1 have the binding domain specific for RalGDS, however, Rap1 has higher affinity to RalGDS than Ras and promotes the translocation of RalGDS to the compartment where Ral is not found, providing a mechanism that Rap1 sequesters RalGDS to prevent Ral activation (61).
We have previously reported that GH-stimulated formation of GTP-bound RalA and RalB occurs in a biphasic manner (29). It is therefore interesting to note that GH-stimulated activation of RalA occurs earlier than that of Rap1 and the trough of GH-stimulated RalA activity is coincident with the sustained phase of GH-stimulated Rap1 activation. Furthermore, when GH-stimulated formation of GTP-bound Rap1 decreased at 30 min, GH-stimulated RalA activity peaked simultaneously for the second time. Rap1 is therefore presumably involved in a cellular mechanism to limit the ability of GH to maintain elevated p44/42 MAP kinase activity but without interference in the initial activation of p44/42 MAP kinase by GH. It is also noteworthy that GH can activate RalA even at a concentration as low as 0.005 nM whereas full activation of Rap1 by GH is observed at concentrations of 550 nM. Secretion of GH is sexually dimorphic in most species to date (62) and is responsible for male specific growth patterns. The sexually dimorphic pattern of secretion is characterized in males by consecutive peaks and troughs in GH serum concentration (62, 63). In rats, the peak values of GH can be greater than 200 ng/ml (about 8 nM) and trough values are less than 1 ng/ml (about 0.05 nM) (63). Our results suggest that Rap1, unlike RalA, would be activated by GH only when the pulsatile GH secretion reaches the peak which would subsequently attenuate RalA activity and subsequent p44/42 MAP kinase activity. How the differential activation of RalA and Rap1 relates to the sexually dimorphic response of mammals to GH needs to be determined. p44/42 MAP kinase activity is also pertinent to aberrant signaling in human cancer and constitutive activation of this kinase has been observed in some tumors (64). Attenuation of GH-stimulated p44/42 MAP kinase activity by Rap1 would therefore limit the oncogenic potential of GH. The limiting effect of Rap1 on GH-stimulated p44/42 MAP kinase activity is consistent with previous reports concerning the ability of Rap1 to reverse oncogenic transformation (6). In agreement with our findings, other groups have also demonstrated that both LPA and EGF can induce a substantial Rap1 activation and Rap1V12 (constitutive Rap1-GTP) attenuates the activation of p44/42 MAP kinases by those mitogens (44, 57, 65). Furthermore, CrkII, identified in this report as an upstream activator of Rap1, has also been demonstrated previously to inhibit p44/42 MAP kinase activation by GH (41). Therefore we have identified a pathway mediated through CrkII-C3G-Rap1, which modulates GH-stimulated p44/42 MAP kinase activity by suppression of RalA. This negative regulatory pathway may be pivotal to ensure precise regulation of GH-stimulated p44/42 MAP kinase signaling.
We have previously demonstrated that CrkII is utilized by GH for activation of JNK/SAPK (21). Here we have further demonstrated that C3G-dependent activation of Rap1 is required for CrkII enhancement of GH-stimulated JNK/SAPK activation. C3G has previously been reported to be upstream of JNK/SAPK and a CrkII-C3G complex is believed to activate JNK/SAPK through a pathway involving the MLK family proteins (66, 67) However, neither the dominant-negative Rap1S17N nor functionally deficient C3G-Y504F can prevent hGH-stimulated JNK/SAPK activation in NIH-3T3 cells suggesting that there must also exist CrkII-C3G-independent pathways for the activation of JNK/SAPK by GH (see Fig. 10). One possible molecule is via the adaptor protein Nck, and we have previously demonstrated that Nck is phosphorylated by cellular stimulation with GH (21). Nck connects to the JNK/SAPK pathway by association with SH3 domain-associated protein serine/threonine kinases such as PAK or NIK (68, 69). One recent report has also demonstrated that gastrin-stimulated JNK/SAPK activation is Src-dependent but CrkII-independent (70). It has been proposed multidomain scaffold proteins, such as JIP, axin, and arrestin regulate JNK activation in response to different stimuli (70). A SHP-2-dependent JNK/SAPK activation by insulin has also been identified (71). This pathway is mediated by H-Ras and not CrkII, because Rac, known as the major downstream effector for CrkII-dependent JNK/SAPK activation, is not required for insulin-stimulated JNK/SAPK activation (71). Thus, GH may utilize the CrkII-independent pathways described above for the activation of JNK/SAPK, in addition to CrkII-C3G-Rap1 pathway described herein, in cells where the endogenous level of CrkII is minimal such as NIH-3T3 cells utilized for this study. CrkII may also utilize other effector molecules to activate JNK/SAPK in response to GH, such as Rac and R-Ras, which are required for v-Crk-dependent JNK/SAPK activation (72). However as the CrkII enhancement of GH-stimulated JNK/SAPK activity is largely inhibited by C3G-Y504F or Rap1S17N (this study), it is likely that C3G-Rap1 is the major pathway downstream of CrkII required for activation of JNK/SAPK by GH. The activation of JNK/SAPK by GH provides another pathway by which GH may affect cellular function. JNK/SAPK is involved in many cellular processes, including transcriptional regulation, proliferation and apoptosis (73) and it is likely that GH utilizes JNK/SAPK for some of these purposes. Although there is considerable evidence demonstrating that activation of JNK/SAPK and c-Jun can trigger apoptosis, reports have also accumulated that JNK/SAPK signaling to c-Jun can inhibit apoptosis and promote proliferation dependent on cell type and stimulus (74). In fibroblasts, the replacement of Ser-63 and Ser-73 of c-Jun by nonphosphorylable alanines results in defective proliferation and loss of protection from apoptosis induced by UV irradiation (75). The phosphorylation of c-Jun on Ser-63 and Ser-73 by JNK/SAPK increases its transcriptional activity (76, 77). Thus, GH may utilize JNK/SAPK to execute its documented proliferative and anti-apoptotic effects (19) in a CrkII-dependent or -independent manner, determined by the expression level of CrkII in a specific cell line.
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In summary, we have demonstrated here that GH stimulates the formation of GTP-bound Rap1 and Rap2 in NIH-3T3 cells. GH-stimulated activation of Rap is predominantly mediated by c-Src-dependent tyrosine phosphorylation of C3G. GH utilizes the inhibitory effect of Rap1 to limit activation of p44/42 MAP kinase pathway via inhibition of RalA. In addition, we have demonstrated that the CrkII-C3G-Rap1 pathway is utilized by GH as a molecular switch from p44/42 MAP kinase signaling to JNK/SAPK signaling. A diagram summarizing GH utilization of the Ras-like small GTPases to regulate MAP kinase pathways is provided in Fig. 10. The identification of another JAK2-independent signaling pathway by GH will dramatically increase our understanding of the mechanisms utilized by GH to achieve its pleiotropic cellular effects.
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FOOTNOTES |
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To whom correspondence should be addressed: Institute of Molecular and Cell
Biology, 30 Medical Dr., Singapore 117609, Republic of Singapore. Tel.:
65-68747847; Fax: 65-67791117; E-mail:
mcbpel{at}imcb.a-star.edu.sg.
1 The abbreviations used are: MAP, mitogen-activated protein; GEFs, guanine
nucleotide exchange factors; JNK, Jun N-terminal kinase; JAK, Janus kinase;
GAP, GTPase-activating protein; EGF, epidermal growth factor; GH, growth
hormone; GST, glutathione S-transferase; STAT, signal transducers and
activators of transcription; ECM, extracellular matrix; IL, interleukin; SAPK,
stress-activated protein kinase.
2 L. Ling and P. Lobie, unpublished observations.
3 S. Mukhina, H. Mertani, K. Guo, and P. E. Lobie, manuscript in
preparation.
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REFERENCES |
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