Activation of Nuclear Factor of Activated T Cells-(NFAT) and Activating Protein 1 (AP-1) by Oncogenic 70Z Cbl Requires an Intact Phosphotyrosine Binding Domain but Not Crk(L) or p85 Phosphatidylinositol 3-Kinase Association*

Jeroen E. M. van LeeuwenDagger , Paul K. Paik, and Lawrence E. Samelson

From the Cell Biology and Metabolism Branch, NICHD, National Institutes of Health, Bethesda, Maryland 20892

    ABSTRACT
Top
Abstract
Introduction
References

The Cbl proto-oncogene product is a complex adapter protein that functions as a negative regulator of protein tyrosine kinases. It is rapidly tyrosine-phosphorylated and associates with Crk(L) and p85 phosphatidylinositol 3-kinase (PI3K) upon engagement of numerous receptors linked to tyrosine kinases. Elucidation of the mechanism(s) underlying Cbl deregulation is therefore of considerable interest. The 70Z Cbl oncoprotein shows increased baseline tyrosine phosphorylation in fibroblasts and enhances nuclear factor of activated T cells (NFAT) activity in Jurkat T cells. Its transforming ability has been proposed to relate to its increased phosphotyrosine content. We demonstrate that 70Z Cbl shows increased basal and activation-induced tyrosine phosphorylation and association with Crk(L) and p85 PI3K in Jurkat T cells. 70Z Cbl, however, retains the ability to enhance NFAT and activating protein 1 (AP1) activity in the absence of Crk(L)/p85 PI3K association. In contrast, the G306E mutation, which inactivates the phosphotyrosine binding domain of Cbl, blocks NFAT/AP1 activation by 70Z Cbl. We conclude that 70Z Cbl-induced NFAT/AP1 activation requires the phosphotyrosine binding domain but not Crk(L)/p85 PI3K association. We hypothesize that 70Z Cbl acts as a dominant negative by blocking the negative regulatory function of the Cbl phosphotyrosine binding domain on protein-tyrosine kinases.

    INTRODUCTION
Top
Abstract
Introduction
References

The proto-oncogene product c-Cbl is a ubiquitously expressed complex adapter protein that associates with numerous signaling molecules in a variety of cell types (reviewed in Ref. 1). It was originally identified as a viral oncogene product (v-Cbl) that causes B-lymphomas and myeloid leukemias in mice (2). Cloning of its cellular homolog revealed that c-Cbl is a 906 amino acid protein that lacks any obvious catalytic domain (3). It contains a N-terminal phosphotyrosine binding (PTB)1 domain (4, 5), a C3HC4 ring finger motif (6), a proline-rich region that includes a binding site for the Grb2 SH3 domain (7), and a C-terminal region that includes several tyrosine residues located within consensus binding sequences for the SH2 domain containing Crk and p85 PI3K adapter proteins (8). A Cbl-related molecule called Cbl-b has been cloned in humans (9), and Cbl homologs have been identified in Drosophila melanogaster (D-Cbl) (10, 11) and Caenorhabditis elegans (Sli-1) (12).

Cbl is rapidly tyrosine-phosphorylated in response to engagement of numerous receptors that activate protein-tyrosine kinases, including immunoreceptors, receptor protein-tyrosine kinases, hematopoietic growth factor receptors, and integrins, as well as oncogenic tyrosine kinases. Tyrosine-phosphorylated Cbl associates with the SH2 domains of the adapter proteins Crk(L) and/or p85 PI3K upon engagement of many of these receptors (reviewed in Ref. 1). Similar to Grb2, Crk family adapter proteins are composed almost exclusively of SH2 and SH3 domains. CrkI and CrkII are alternatively spliced products of a single gene that contain a N-terminal SH2 domain followed by one or two SH3 domains, respectively (13). CrkL is the product of a different gene; it has a structural organization similar to CrkII (14). Several studies have indicated that Crk(L) proteins may promote transformation, either when expressed as truncated isoforms or when overexpressed (13, 15, 16). Moreover, a multimolecular complex of Abl, CrkL, Cbl, and, possibly, p85 PI3K has been postulated to mediate, at least in part, the transforming ability of oncogenic Abl (16-19). Interestingly, Crk(L) proteins associate through their N-terminal SH3 domain with C3G (20), a guanine nucleotide exchange factor for the small GTPase Rap1 (21, 22). In various model systems, overexpression of Rap1 can antagonize Ras signaling, presumably through competitive inhibition of Ras-GTP binding to downstream effector molecules (Ref. 23 and references therein). Thus, it is possible that the interaction of Cbl with Crk(L) regulates Ras signaling through C3G and Rap1 and that Cbl serves as a docking protein to recruit the Crk(L)-C3G complex (24). This is analogous to the well described role of activated receptor tyrosine kinases, which recruit the Grb2-Sos complex to the plasma membrane to activate membrane-bound Ras (25). Elucidation of the functional significance of the Cbl-Crk(L)/p85 PI3K interaction for normal as well as oncogenic protein-tyrosine kinase signaling pathways is therefore of considerable interest.

Several lines of evidence indicate that Cbl functions as a negative regulator of protein-tyrosine kinase signaling pathways. First, in the flatworm C. elegans, the G315E loss-of-function allele of Sli-1 rescues vulval development induced by a reduction-of-function allele of the Let23 epidermal growth factor receptor homolog (12). Second, in D. melanogaster, overexpression of D-Cbl in transgenic flies inhibits the sevenless protein-tyrosine kinase-induced development of the R7 photoreceptor neuron (11). Finally, in RBL 2H3 mast cells, overexpression of mammalian Cbl inhibits Fcepsilon RI-induced Syk-tyrosine kinase activity and serotonin release (26). Given the strong evolutionary conservation of the N-terminal half of the Cbl protein and the observation that the Cbl G306E mutation, which corresponds to the Sli-1 G315E loss-of-function mutation, inactivates its PTB domain (4, 5), it is possible that the negative regulation of protein-tyrosine kinase signaling pathways by mammalian Cbl requires direct interaction of its PTB domain with protein-tyrosine kinases.

Several oncogenic variants of the c-Cbl proto-oncogene product have been identified. The c/v-Cbl oncoprotein (also referred to as Cbl-N) consists of the N-terminal 357 amino acids of the c-Cbl protein, which includes the PTB domain (2, 3). Introduction of the G306E mutation into c/v-Cbl blocks its association with activated (receptor) tyrosine kinases in vivo (5, 27, 28), as well as its transforming activity in vitro (27). Thus, it was proposed that transformation caused by overexpression of c/v-Cbl results from competitive inhibition of endogenous Cbl binding to phosphotyrosine residues on activated protein-tyrosine kinases, thereby blocking the negative regulatory role of Cbl on tyrosine kinases (27). Interestingly, the oncogenic 70Z Cbl mutant protein, which contains a 17-amino acid internal deletion including the N-terminal cysteine residue of the Ring finger, shows increased baseline tyrosine phosphorylation in fibroblasts (28-30) and enhances NFAT transcription in Jurkat T cells (31). Here, we tested two alternative models that have been suggested to explain 70Z Cbl-mediated transformation and activation of NFAT in Jurkat T cells. In the first model, 70Z Cbl acts through increased tyrosine phosphorylation and association with Crk(L) and p85 PI3K adapter proteins, which may lead to deregulation of Rap1 and, perhaps, Ras activation. In the second model, 70Z Cbl acts through its PTB domain, possibly to competitively inhibit the PTB domain dependent regulatory function of endogenous Cbl on protein-tyrosine kinases. Our study demonstrates that 70Z Cbl-induced NFAT/AP1 activation requires an intact PTB domain but not Crk(L) or p85 PI3K interaction. Our findings are most consistent with the possibility that 70Z Cbl acts as a dominant negative to inhibit the negative regulatory role of endogenous Cbl on protein-tyrosine kinases.

    EXPERIMENTAL PROCEDURES

Cell Lines and Antibodies-- Jurkat E6.1 and Jurkat-TAg (32) cell lines were maintained in RPMI medium supplemented with 10% fetal bovine serum (FBS) at a cell density of 0.1 to 1 × 106 cells/ml. HuTK- and CV-1 cells were maintained in Dulbecco's modified Eagle's medium/10% FBS. The following antibodies (Abs) were used in this study: 4G10 anti-phosphotyrosine and anti-p85 PI3K from Upstate Biotechnology; anti-Crk from Transduction Laboratories; anti-Erk2, anti-CrkII, anti-CrkL, and anti-Cbl (C15) from Santa Cruz; anti-active MAPK from Promega; and anti-hemagglutinin (HA) (12CA5) from Boehringer Mannheim and anti-Myc (9E10) ascites.

cDNA Constructs-- pSX SRalpha , pSX HA Cbl, and pSX HA 70Z were described previously (7). pSX HA Cbl Y700F, Y774F and Y700F/Y731F/Y774F were made by subcloning a 3.0-kilobase BamHI fragment from the corresponding pAlter constructs (gifts from Wallace Y. Langdon) (33) into the BglII site of pSX SRalpha . pSX HA Cbl Y700F/Y774F was made by site directed mutagenesis of pSX HA Cbl Y774F using the Quick Change site-directed mutagenesis kit (Stratagene) and oligos 5'-TGAAGAGGACACAGAATTCATGACTCCCTCTTC-3' (sense) and 5'-GAAGAGGGAGTCATGAATTCTGTGTCCTCTTCA-3' (antisense), thereby creating a diagnostic EcoRI site. The construct was verified by sequencing. pSX HA 70Z Y700F, Y774F, Y700F/Y774F, and Y700F/ Y731F/Y774F were made by replacing coding sequences 3' of the unique BglII site from pSX HA 70Z with the same fragments from the corresponding pSX HA Cbl mutant constructs. pSX HA 70Z G306E was made using the Quick Change site-directed mutagenesis kit (Stratagene) and oligos 5'-CAGTGGGCTATTGAGTATGTTACTGC-3' and 5'-GCAGTAACATACTCAATAGCCCACTG-3'. The construct was verified by sequencing. pSC65, pSC65 HA Cbl, and pSC65 HA 70Z were described previously (34). pSC65 HA Cbl Y700F and Y774F were made by subcloning a 3.0-kilobase BamHI fragment from pALTER HA Cbl Y700F or Y774F (gifts from W. Langdon) (33) into the BglII site of pSC65. pSC65 HA Cbl Y700F/Y774F and Y700F/Y731F/Y774F, pSC65 HA 70Z Y700F, and Y774F, Y700F/Y774F, and Y700F/Y731F/Y774F were made by replacing the coding sequences 3' of the unique BglII site with the corresponding fragments from pSX HA Cbl constructs carrying the appropriate tyrosine to phenylalanine mutations. An N-terminal 9-amino acid Myc epitope-tag was inserted into the SalI-NcoI sites of pAK10 CrkI, CrkI R38V, CrkI W169L, and CrkII (gifts from M. Matsuda) (35) using oligos 5'-TCGACATGGAGCAGAAGCTGATCAGCGAGGAGGACTTGGCCATG-3' (sense) and 5'-GATCCATGGCCAAGTCCTCCTCGCTGATCAGCTTCTGCTCCATG-3' (antisense). The con- structs were verified by sequencing. pSC65 Myc CrkI, Myc CrkI W169L, and Myc CrkII were made by subcloning the SalI-KpnI fragment of the corresponding pAK10 constructs into the SalI-KpnI sites of pSC65. pSC65 Myc CrkI R38V was made by replacing the 915-base pair NcoI fragment from pSC65 Myc CrkI with that from the corresponding pAK10 Myc CrkI R38V construct.

Expression of Recombinant Vaccinia Virus-- Recombinant vaccinia virus was made by standard procedures. Briefly, near confluent CV-1 cells were infected in 25-cm2 flasks for 2 h with wild-type WR' strain TK+ vaccinia virus at a multiplicity of infection of 0.25 and transfected overnight with 20 µg of the appropriate constructs using Lipofectin in Opti-MEM medium (Life Technologies, Inc.) followed by an additional 24 h of culture in Dulbecco's modified Eagle's medium/10% FBS. Infected/transfected cells were harvested by centrifugation and lysed by repeated cycles of freeze-thawing and sonication. Blue recombinant TK- plaques were purified by three rounds of plaque purification on confluent HuTK- in 1% low melting agarose/1× basal medium Eagle (Life Technologies, Inc.)/5% FBS and three rounds of amplification in Dulbecco's modified Eagle's medium/10% FBS in the continuous presence of 25 µg/ml BrdUrd (Sigma). Crude viral stocks were titered on HuTK- cells and used to infect Jurkat T cells at a multiplicity of infection of 5. After 15 h, infected Jurkat T cells were harvested. Cell viability was routinely determined by trypan blue exclusion and always exceeded 95%.

OKT3 Stimulation, Immunoprecipitation, SDS-PAGE, and Immunoblotting-- Jurkat T cells were washed once in ice-cold RPMI medium without FBS and resuspended at 1 × 108 cells/ml. Generally, 1-2 × 107 cells were preincubated at 37 °C for 5 min, before cross-linking CD3 by addition of OKT3 ascites (1:100). Cells were incubated at 37 °C for the indicated time periods and solubilized for 30 min on ice in lysis buffer containing 150 mM NaCl, 25 mM Tris, pH 7.5, 1 mM Na3VO4, 1 mM phenylmethylsulfonyl fluoride, 10 mg/ml aprotonin and leupeptin, and 1% Brij97 or another detergent as indicated. Immunoprecipitation of postnuclear lysates, denaturing SDS-PAGE, and immunoblotting were performed according to standard procedures.

Transient Tranfection and SEAP Reporter Gene Assays-- Secreted alkaline phosphatase (SEAP) reporter gene constructs composed of multimers of the NFAT or AP1 response elements (NFAT-SEAP and AP1-SEAP) were kindly provided by G. Crabtree (32). In general, 1 × 107 Jurkat-TAg cells were transfected with 5 µg of reporter construct and 10 µg of test construct by electroporation using the Bio-Rad gene pulser (310 kV, 200 ohms, 960 microfarad). Transfected Jurkat-TAg cells were cultured in bulk for 24 h and subsequently stimulated in duplicate with immobilized OKT3 (1 µl of ascites/well), PMA (Sigma) at 10 ng/ml, ionomycin (Calbiochem) at 1 µg/ml or PMA plus ionomycin in 1 ml of phenol red-deficient RPMI/10% FBS at a density of 3 × 106 transfected cells/ml. After stimulation for 15 h, cell cultures were incubated for 1 h at 65 °C to inactivate endogenous phosphatases, and supernatants were assayed in duplicate at 37 °C for SEAP activity using p-nitrophenyl phosphate (Sigma) at 1.8 mg/ml in diethanolamine bicarbonate, pH 10.0, as a substrate. Absorbance at 405 nm was determined using a MR 5000 microtiter plate reader (Dynatech), usually between 6 and 12 h of incubation. Presented data are representative of at least three independent experiments.

    RESULTS

70Z Cbl Shows Increased Basal and Activation-induced Tyrosine Phosphorylation and Association with Crk(L) and p85 PI3K in Jurkat T Cells-- The oncogenic 70Z/3 mutant form of Cbl undergoes increased baseline tyrosine phosphorylation in fibroblasts (28-30). To determine whether increased tyrosine phosphorylation of 70Z Cbl could also be observed in T cells, Jurkat T cells were infected with recombinant vaccinia virus expressing HA-tagged wt or 70Z Cbl proteins. Infected cells were stimulated with anti-CD3epsilon mAb, and tyrosine phosphorylation of HA immunoprecipitates was evaluated by immunoblotting. As shown in Fig. 1A, 70Z Cbl displays increased basal and activation-induced tyrosine phosphorylation relative to wt Cbl (compare lanes 3 and 4 with lanes 5 and 6). In contrast to the observed differences in their phosphotyrosine content, wt and 70Z Cbl showed similar kinetics of tyrosine phosphorylation with maximal levels obtained after 2 min of stimulation and returning to baseline levels after 20-40 min of stimulation (Fig. 1B). These kinetics closely resembled those of endogenous Cbl (data not shown). These results suggest that increased tyrosine phosphorylation of 70Z Cbl is a more general phenomenon, as it occurs in cell types as different as fibroblasts and T cells.


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Fig. 1.   70Z Cbl shows increased basal and CD3-induced tyrosine phosphorylation in Jurkat T cells. A, Jurkat T cells were infected for 15 h with recombinant vaccinia virus generated with vector alone (pSC65) or vector encoding HA-tagged wt Cbl (HA Cbl) or 70Z Cbl (HA 70Z). Cells were stimulated for 2 min in the presence or absence of OKT3 mAb and solubilized in 1% Brij97 lysis buffer, and postnuclear lysates were immunoprecipitated (IP) with anti-HA mAb, followed by SDS-PAGE and sequential immunoblotting (IB) with anti-phosphotyrosine (4G10) and anti-HA mAbs as indicated. The band detected in the anti-HA immunoblot (lower panel) of pSC65 infected cells that migrates just above Cbl is a background band caused by HA blotting and does not represent Cbl, as it is not detected by anti-Cbl blotting (see also Fig. 3). B, after infection with either HA Cbl or HA 70Z, Jurkat T cells were stimulated with OKT3 mAb for the indicated time periods and lysed in 1% Brij97 lysis buffer, and postnuclear lysates were immunoprecipitated (IP) with anti-HA mAb followed by SDS-PAGE and sequential immunoblotting (IB) with anti-phosphotyrosine (4G10) and anti-Cbl (C15) Abs as indicated.

Activation-induced tyrosine phosphorylation of endogenous Cbl leads to its association with Crk(L) and p85 PI3K adapter proteins (reviewed in Ref. 1). In order to determine whether increased tyrosine phosphorylation of 70Z Cbl leads to increased association with these adapter proteins, Jurkat T cells were infected with recombinant vaccinia virus encoding HA-tagged wt or 70Z Cbl and stimulated with anti-CD3epsilon mAb, and lysates were immunoprecipitated with anti-CrkII or anti-CrkL Abs followed by anti-HA immunoblotting. Both CrkII (Fig. 2, top two panels) and CrkL (Fig. 2, third and fourth panels from top) showed increased basal and activation-induced association with 70Z relative to wt Cbl (compare lanes 3 and 4 with lanes 5 and 6). This was not due to differences in the level of Cbl protein expression, as anti-HA immunoblotting revealed that wt and 70Z Cbl were expressed at similar levels (Fig. 2, bottom panel). Myc epitope-tagged CrkI (see Fig. 4) as well as p85 PI3K (see Fig. 5) also showed increased association with 70Z relative to wt Cbl in unstimulated and anti-CD3-stimulated Jurkat T cells. Taken together, these findings demonstrate that increased basal and activation-induced tyrosine phosphorylation of 70Z relative to wt Cbl leads to increased association with Crk(L) and p85 PI3K adapter proteins.


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Fig. 2.   70Z Cbl proteins show increased basal and CD3-induced association with Crk(L) adapter proteins. Jurkat T cells were infected, stimulated with OKT3, and solubilized as in Fig. 1A. Postnuclear lysates were immunoprecipitated (IP) with anti-CrkII, anti-CrkL, or anti-HA Abs followed by SDS-PAGE and (sequential) immunoblotting (IB) with anti-HA and anti-Crk, anti-HA and anti-CrkL, or anti-HA, respectively.

Activation-induced Tyrosine Phosphorylation of Cbl Is Not Restricted to Phosphotyrosine Residues 700, 731, and 774-- To further characterize the tyrosine phosphorylation and interaction of wt and 70Z Cbl proteins with Crk(L) and p85 PI3K in vivo, we generated recombinant vaccinia viruses encoding wt or 70Z Cbl carrying tyrosine to phenylalanine mutations in Tyr-700, Tyr-731, and/or Tyr-774. Tyr-700 and Tyr-774 are located within a consensus sequence for binding to the SH2 domains of Crk, whereas Tyr-731 is predicted to bind the p85 PI3K SH2 domain (8). Furthermore, in vitro analysis has revealed that the Crk SH2 domain binds to the phosphotyrosine residue 774 (24, 36). However, in Abl transformed cells, CrkL association with wt Cbl is decreased but not absent when either Y700F or Y774F point mutations are introduced into Cbl (33), suggesting that the CrkL SH2 domain associates with both phosphotyrosine residues. p85 PI3K association with Cbl has been previously mapped to phosphotyrosine 731 in vitro (24) and in vivo (31, 37). To determine whether simultaneous mutation of Tyr-700, Tyr-731, and Tyr-774 to phenylalanine leads to loss of wt and 70Z Cbl tyrosine phosphorylation, Jurkat T cells were infected with recombinant vaccinia virus encoding various Cbl constructs and tyrosine phosphorylation of Cbl proteins evaluated in the absence or presence of anti-CD3 stimulation. Interestingly, wt and 70Z Cbl carrying the Y700F/Y774F and, more importantly, the Y700F/Y731F/Y774F mutations showed anti-CD3-induced tyrosine phosphorylation (Fig. 3), indicating that a tyrosine(s) other than Tyr-700, Tyr-731, and Tyr-774 undergoes activation-induced phosphorylation. Moreover, as seen for Tyr-700, Tyr-731, and Tyr-774, at least one of these additional tyrosines undergoes increased phosphorylation in 70Z relative to wt Cbl (Fig. 3). As we have been unable to detect tyrosine phosphorylation of Cbl 1-655 truncation constructs (Ref. 34 and data not shown), it seems that these additional tyrosine residues are located in the C-terminal region (amino acids 655-906) of Cbl. Consistent with this idea, Cbl contains four additional tyrosine residues in that region, i.e. Tyr-674, Tyr-735, Tyr-869, and Tyr-871 (3).


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Fig. 3.   Wild-type and 70Z Cbl proteins undergo activation-induced phosphorylation on tyrosines other than Tyr-700, Tyr-731, and Tyr-774. Jurkat T cells were infected with recombinant vaccinia virus as indicated and stimulated for 2 min in the presence or absence of OKT3, and postnuclear Brij97 lysates were immunoprecipitated (IP) with anti-HA mAbs followed by SDS-PAGE and sequential immunoblotting (IB) with anti-phosphotyrosine (4G10) and anti-Cbl (C15) Abs.

Disruption of Crk(L) and p85 PI3K Association with wt and 70Z Cbl Carrying the Y700F/Y731F/Y774F Triple Mutation-- To further characterize the molecular basis for the interaction between Cbl and Crk(L)/p85 PI3K proteins in vivo, we analyzed the interaction of Myc epitope-tagged CrkI, as well as endogenous CrkII and CrkL with wt or 70Z Cbl carrying Y700F, Y731F, and/or Y774F mutations. Recombinant vaccina virus carrying Myc epitope-tagged CrkI was generated for this purpose. As previously mentioned, Myc CrkI displayed increased association with 70Z relative to wt Cbl in both unstimulated and anti-CD3-stimulated Jurkat T cells (Fig. 4A, compare lanes 3 and 4 with lanes 9 and 10). Furthermore, both Y700F and Y774F single point mutations reduced, but did not eliminate, binding of CrkI to wt and 70Z Cbl (Fig. 4A, compare lanes 5-8 with lanes 3 and 4 and lanes 11-14 with lanes 9 and 10). Identical results were obtained also for coprecipitation of wt and 70Z Cbl with endogenous CrkII and CrkL (data not shown). In contrast, wt and 70Z Cbl carrying the double (Y700F/Y774F) or triple (Y700F/Y731F/Y774F) mutation failed to show basal and activation-induced association with CrkI (Fig. 4B, compare lanes 5-8 with lanes 3 and 4 and lanes 11-14 with lanes 9 and 10), as well as with endogenous CrkII and CrkL (data not shown). Additional experiments using Myc epitope-tagged Crk proteins that contain a mutation that inactivates its SH2 (R38V) or SH3 (W169L) domain confirmed that the interaction between Cbl and Crk is mediated through the SH2 but not the SH3 domain of Crk in vivo (data not shown).


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Fig. 4.   Crk(L) adapter proteins do not associate with wt or 70Z Cbl carrying the Y700F/Y774F mutation. A, Jurkat T cells were co-infected with recombinant vaccinia virus as indicated and stimulated for 2 min in the presence or absence of OKT3 mAb, and postnuclear Brij97 lysates were immunoprecipitated (IP) with anti-Myc mAb. Because Myc CrkI exactly co-migrates with the immunoglobulin light chain of the immunoprecipitating Ab, equal amounts were run in parallel in reducing and nonreducing SDS-PAGE followed by immunoblotting (IB) with anti-HA (top panel) or anti-Myc (middle panel) mAbs, respectively. In addition, whole cell lysates (WCL) were immunoblotted with anti-HA mAb to determine the expression levels of Cbl proteins (bottom panel). B, Jurkat T cells were co-infected with recombinant vaccinia virus as indicated and further treated as described in A.

We also analyzed the interaction of p85 PI3K with various wt and 70Z Cbl constructs. Initial experiments revealed that following solubilization in Brij97, p85 coprecipitated via the OKT3 mAb with the activated T cell receptor/CD3 complex (data not shown). To exclude the possibility that p85 PI3K could be detected in anti-HA immunoprecipitates as a consequence of its association with the activated TCR/CD3 complex rather than Cbl proteins, we instead used Triton X-100 to solubilize the cells. As shown in Fig. 5A, we could not detect activation-induced coprecipitation of p85 PI3K in anti-HA immunoprecipitates of vector infected Jurkat T cells under these conditions (Fig. 5A, lanes 1 and 2). We did detect a faint background band in both unstimulated and anti-CD3-stimulated vector-infected Jurkat T cells that comigrated with p85 PI3K. Nevertheless, we clearly observed increased p85 PI3K binding to wt Cbl in anti-CD3-stimulated relative to unstimulated HA Cbl infected Jurkat T cells (Fig. 5A, compare lanes 3 and 4 with lanes 1 and 2), as well as increased basal and activation-induced p85 PI3K association with 70Z relative to wt Cbl (Fig. 5A, compare lanes 7 and 8 with lanes 3 and 4). Significantly, anti-HA immunoblotting of anti-p85 PI3K immunoprecipitates more clearly revealed increased association of p85 PI3K with 70Z relative to wt Cbl when compared with anti-p85 PI3K immunoblotting of anti-HA immunoprecipitates (compare Fig. 5B and Fig. 5A). Even though p85 PI3K was readily observed in anti-HA immunoprecipitates of HA Cbl expressing cells (Fig. 5A, lanes 3 and 4), activation-induced coprecipitation of HA-tagged Cbl with p85 PI3K could barely be detected (Fig. 5B, lanes 3 and 4). These findings are consistent with the possibility that overexpressed HA Cbl associates with a small fraction of total p85 PI3K, whereas the overexpressed and heavily tyrosine-phosphorylated 70Z Cbl protein associates with a large fraction of total p85 PI3K. Importantly, and consistent with published data (24, 31, 37), p85 PI3K did not associate with wt or 70Z Cbl carrying the Y700F/Y731F/Y774F triple mutation (Figs. 5, A and B, compare lanes 5 and 6 with lanes 3 and 4, and lanes 9 and 10 with lanes 7 and 8). Taken together, our findings demonstrate that Crk(L) proteins interact through their SH2 domains with both phosphotyrosine residues 700 and 774 in wt and 70Z Cbl proteins in vivo, and that simultaneous mutation of Tyr-700, Tyr-731, and Tyr-774 disrupts interaction of Crk(L) and p85 PI3K with wt and 70Z Cbl.


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Fig. 5.   p85 PI3K does not associate with wt or 70Z Cbl proteins carrying the Y700F/Y731F/Y774F mutation. A, Jurkat T cells were infected with recombinant vaccinia as indicated and stimulated for 2 min in the presence or absence of OKT3, and postnuclear Triton X-100 lysates were immunoprecipitated with anti-HA followed by SDS-PAGE and sequential immunoblotting with anti-p85 PI3K and anti-HA Abs. Anti-p85 PI3K immunoblotting generated a background signal (as seen in pSC65-infected cells) that comigrated with endogenous p85. Whole cell lysates (WCL) were also immunoblotted with anti-HA to document equal expression of the HA-tagged wt and 70Z Cbl constructs (bottom panel). B, Jurkat T cells were infected, stimulated, and lysed as in A, and lysates were immunoprecipitated (IP) with anti-p85 PI3K mAb followed by SDS-PAGE and sequential immunoblotting (IB) with anti-HA and anti-p85 PI3K Abs. The top panel was overexposed to visualize the presence of small amounts of HA Cbl in p85 immunoprecipitates. Shorter exposures revealed differences in p85 PI3K association with 70Z Cbl in unstimulated and stimulated cells. Whole cell lysates (WCL) were immunoblotted with anti-HA mAb to document similar expression levels of Cbl proteins.

Disruption of Crk(L)/p85 PI3K Interaction with wt and 70Z Cbl Does Not Affect Erk MAPK Activation-- Crk(L) proteins associate through their N-terminal SH3 domain with C3G (20), a guanine nucleotide exchange factor for the small G protein Rap1 (21). Overexpression of Crk(L) and C3G has been reported to activate Rap1 (38). In various model systems, overexpression of Rap1 can antagonize Ras signaling, presumably through competitive inhibition of Ras-GTP binding to downstream effector molecules (Ref. 23 and references therein). In Jurkat T cells, activation of the Ras effector protein Raf results in activation of the dual specificity MAP kinase kinases MEK1/2 that, in turn, activate the MAP kinases Erk1/2 (39). In order to determine whether interaction of Crk(L) with wt or 70Z Cbl had any effect on Ras signaling, we analyzed the effect of overexpression of various Cbl constructs on the activation of MAP kinases Erk1 and Erk2. Thus, Jurkat T cells were infected with recombinant vaccinia virus expressing the various wt and 70Z Cbl proteins, and activation of Erk1/2 was evaluated by immunoblotting whole cell lysates with anti-active MAPK Ab. Neither overexpression of 70Z Cbl nor overexpression of the Y700F/Y774F or Y700F/Y731F/Y774F mutant derivatives of wt and 70Z Cbl showed any significant and reproducible effect on basal or anti-CD3-induced activation of Erk1/2 relative to wt Cbl or the vector control (Fig. 6). Moreover, none of the wt or 70Z Cbl proteins had any effect on basal or anti-CD3-induced Erk activation upon prolonged stimulation (data not shown), excluding the possibility that 70Z Cbl induces prolonged Erk activation relative to wt Cbl or the vector control. These results demonstrate that increased basal and activation-induced association of 70Z Cbl with Crk(L) and p85 PI3K does not detectably affect Erk1/2 activation, suggesting that the Cbl-Crk(L) and Cbl-p85 PI3K interactions do not regulate Ras signaling in Jurkat T cells.


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Fig. 6.   Interaction between Cbl and Crk(L) or p85 PI3K does not affect basal or CD3-induced Erk1/2 activation. Jurkat T cells were infected with recombinant vaccinia virus as indicated, stimulated for 5 min in the absence or presence of OKT3, and lysed in 1% Triton X-100 lysis buffer, and whole cell lysates (WCL) were immunoblotted with anti-active MAPK or anti-HA Abs.

70Z Cbl Retains Its Ability to Induce NFAT and AP1 in the Absence of Crk(L)/p85 PI3K Association-- As 70Z Cbl is known to activate the NFAT transcription factor in Jurkat T cells (31), we analyzed the effect of the Cbl-Crk(L) and Cbl-p85 PI3K interactions on transcriptional activation of NFAT and AP1 transcription factors using SEAP reporter gene assays (32). Jurkat-TAg cells were transiently transfected with HA-tagged wt or 70Z Cbl expression constructs together with the appropriate reporter gene construct. Transfected cells were left unstimulated or stimulated with immobilized anti-CD3 mAb, PMA, ionomycin or PMA plus ionomycin, and supernatants were assayed for SEAP reporter gene activity. Results were expressed relative to the response obtained after stimulation with PMA plus ionomycin, which served as an internal control for the SEAP responsiveness between different groups of transfected cells. It should be noted that we did not observe any reproducible effect of overexpressing various Cbl proteins on the absolute response induced by PMA plus ionomycin (data not shown). Overexpression of wt Cbl did not reproducibly and significantly affect NFAT activity under any conditions relative to the vector control (Fig. 7A), nor did overexpression of wt Cbl affect AP1 driven reporter gene activity (Fig. 7B). In contrast, overexpression of 70Z Cbl led to a significant and reproducible increase in NFAT reporter activity in unstimulated cells relative to wt Cbl or the vector control but caused no significant and reproducible changes in response to anti-CD3 mAb (Fig. 7A). Indeed, titration of the anti-CD3 mAb over a 100-fold range did not reveal any significant effect of 70Z relative to wt Cbl on anti-CD3-induced NFAT activation (data not shown). 70Z Cbl also up-regulated AP1 activity in unstimulated cells, although this increase was less pronounced (2-3-fold induction over the vector control) compared with the increase in NFAT activity (5-10-fold induction over the vector control) (Fig. 7B). Overexpression of wt or 70Z Cbl Y700F/Y774F double or Y700F/Y731F/Y774F triple mutants did not lead to significant changes in NFAT or AP1 activity relative to their unmutated counterparts (Fig. 7, A and B). It should be noted that the relatively small increase in NFAT activation induced by 70Z Y700F/Y774F and 70Z Y700F/Y731F/Y774F relative to 70Z Cbl observed in this experiment was not consistently observed. In contrast to the reported cooperation of 70Z Cbl with ionomycin to induce NFAT (31), our results demonstrated that SEAP reporter gene activity in cells stimulated with ionomycin (Fig. 7, A and B) or PMA alone (data not shown) was similar to that observed in unstimulated cells. It should be noted that the observed effects of oncogenic 70Z Cbl proteins on NFAT and AP1 activation were not due to differences in expression levels of Cbl proteins, as evidenced by anti-Cbl immunoblotting of whole cell lysates (Fig. 7C). Taken together, our results demonstrate that (i) 70Z Cbl up-regulates NFAT and AP1 activity in unstimulated Jurkat T cells, (ii) 70Z Cbl does not cooperate with ionomycin to induce NFAT or AP1 activity, and (iii) the 70Z Cbl-induced activation of NFAT and AP1 is not mediated through its interaction with Crk(L) and p85 PI3K adapter proteins.


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Fig. 7.   Activation of NFAT and AP1 by oncogenic 70Z Cbl in unstimulated Jurkat T cells does not require interaction with Crk(L) and p85 PI3K. Jurkat-TAg cells were transiently transfected with vector (pSX SRalpha ) or the indicated Cbl expression constructs together with the NFAT (A) or AP1 (B) reporter gene construct and either left unstimulated or stimulated for 15 h with immobilized OKT3, ionomycin (1 µg/ml), or PMA (10 ng/ml) plus ionomycin. SEAP reporter activity was measured and plotted relative to the response induced by PMA plus ionomycin. C, whole cell lysates (WCL) of the experiments shown in A and B were immunoblotted (IB) for Cbl expression using anti-Cbl (C15) Abs.

Disruption of the PTB Domain Blocks 70Z Cbl-induced NFAT/AP1 Activation-- Thien and Langdon (27, 30) have hypothesized that the mechanisms underlying 70Z Cbl- and v-Cbl-induced transformation are distinct. Specifically, they hypothesized that 70Z Cbl induced transformation results from a positive signal, perhaps related to its increased tyrosine phosphorylation (29, 30), whereas v-Cbl appears to act as a dominant negative by competing with endogenous Cbl for phosphotyrosine residues on activated tyrosine kinases, thereby blocking the putative negative regulatory role of Cbl (27). Such a model appears to be supported by the observations that 70Z Cbl, but not v-Cbl, enhances NFAT activation in Jurkat T cells (Ref. 31 and data not shown), as well as epidermal growth factor receptor kinase activity in unstimulated NIH3T3 cells (30). Furthermore, v-Cbl-induced transformation requires higher levels of expression as compared with 70Z Cbl-induced transformation (30). However, evidence that the molecular mechanism(s) underlying 70Z Cbl- and v-Cbl-induced transformation are different from each other is presently not available. As v-Cbl-induced transformation is blocked by the G306E mutation (27), we analyzed the effect of the G306E mutation on NFAT and AP1 activation induced by 70Z Cbl oncoproteins. Jurkat TAg cells were transiently transfected with HA-tagged 70Z Cbl in either the absence or the presence of the G306E mutation. Activation of NFAT and AP1 transcription factors was assessed in unstimulated Jurkat T cells. Most importantly, the 70Z Cbl oncoprotein but not its G306E mutant derivative up-regulated NFAT and AP1 activity (Fig. 8, A and B), even though 70Z Cbl and its G306E mutant derivative were expressed at similar levels (Fig. 8C). As the PTB domain of Cbl is known to bind to the ZAP70 phosphotyrosine residue 292 in vitro and upon coexpression in Cos cells (4, 5), we next evaluated whether the G306E mutation might also affect tyrosine phosphorylation of the 70Z Cbl oncoprotein. As illustrated in Fig. 8D, the increased tyrosine phosphorylation of 70Z Cbl that is observed in unstimulated and OKT3-stimulated Jurkat T cells is blocked by the G306E mutation and is comparable to that observed in wt Cbl. Taken together, our findings confirm earlier reports that c/v-Cbl does not up-regulate NFAT and AP1 activity (31) and demonstrate that increased tyrosine phosphorylation of 70Z Cbl-induced as well as 70Z Cbl-induced NFAT and AP1 activation requires the presence of an intact PTB domain.


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Fig. 8.   Activation of NFAT and AP1 by oncogenic 70Z Cbl requires an intact PTB domain. Jurkat TAg cells were transiently transfected with vector or the indicated Cbl expression constructs together with NFAT (A) or AP1 (B) reporter gene constructs and either left unstimulated or stimulated for 15 h in the presence of PMA (10 ng/ml) plus ionomycin (1 µg/ml). C, whole cell lysates of the experiments shown in A and B were immunoblotted with anti-Cbl (C15) Abs to verify expression of transfected Cbl proteins. D, Jurkat T cells were infected with recombinant vaccinia virus as indicated and further treated as in Fig. 1A.


    DISCUSSION

The Cbl proto-oncogene product is a ubiquitously expressed complex adapter protein that functions as a negative regulator of protein-tyrosine kinases (1, 11, 12, 26). Cbl is rapidly tyrosine-phosphorylated and associates with Crk(L) and p85 PI3K adapter proteins upon engagement of numerous protein-tyrosine kinase-linked receptors in a variety of cell types (reviewed in Ref. 1). Interestingly, the 70Z Cbl oncoprotein shows increased tyrosine phosphorylation in fibroblasts (28-30) and activates NFAT-mediated transcription in Jurkat T cells (Ref. 31 and this study), but the molecular mechanisms underlying 70Z Cbl-induced NFAT activation and transformation have not been previously identified. Here we demonstrate that 70Z Cbl shows increased basal and CD3-induced tyrosine phosphorylation, leading to increased association with Crk(L) and p85 PI3K adapter proteins in Jurkat T cells. However, disruption of Crk(L) and p85 PI3K association with oncogenic 70Z Cbl did not block NFAT and AP1 activation. In contrast, 70Z Cbl-induced NFAT/AP1 activation was completely blocked by the G306E mutation, indicating that 70Z Cbl requires an intact PTB domain for NFAT/AP1 activation in Jurkat T cells.

Our studies confirm the previous finding (31) that oncogenic 70Z Cbl but not wt or c/v-Cbl activates NFAT and further extends these findings to show that 70Z Cbl also enhances AP1 activity. Our study differs from that of Liu et al. (31) in that we did not detect cooperation of 70Z Cbl with ionomycin to induce NFAT activation, even when Jurkat T cells were stimulated after serum starvation or when using lower concentrations of ionomycin (data not shown). We also did not confirm the data from Rellahan et al. (40), who reported a 3-fold reduction in AP1-mediated reporter activity in cells overexpressing Cbl relative to the vector control. The cause of the discrepancies between our study and these other studies is not clear at present, but we note that we used PMA plus ionomycin stimulation as an internal control to normalize for reporter gene activity between different groups of transfected cells.

The 70Z Cbl oncoprotein shows increased baseline tyrosine phosphorylation in fibroblasts (28-30) and, as demonstrated in this study, in Jurkat T cells. However, the tyrosine residues in 70Z Cbl that undergo increased phosphorylation relative to wt Cbl have not been identified thus far. In vitro studies have previously identified Tyr(P)-774 and Tyr(P)-731 in wt Cbl as binding sites for the SH2 domains of Crk and p85 PI3K, respectively (24, 36). In vivo studies have demonstrated a role for both Tyr(P)-700 and Tyr(P)-774 in CrkL binding in Abl transformed cells (33) and for Tyr(P)-731 in p85 PI3K binding (31, 37). Our studies have confirmed and further extended these findings in determining that CrkI, CrkII, and CrkL associate with both Tyr(P)-700 and Tyr(P)-774 in vivo and that increased phosphorylation of Tyr-700, Tyr-731, and Tyr-774 in 70Z Cbl results in increased recruitment of Crk(L) and p85 PI3K adapter proteins. Interestingly, increased tyrosine phosphorylation of 70Z is not restricted to these three residues, as increased basal and activation-induced phosphorylation was also observed in 70Z Y700F/Y731F/Y774F relative to wt Y700F/Y731F/Y774F Cbl. Our findings apparently contrast with those recently reported by Feshchenko et al. (41), who did not detect appreciable tyrosine phosphorylation of the wt Cbl Y700F/Y731F/Y774F triple mutant in response to pervanadate treatment of transiently transfected Jurkat T cells. We suggest that this difference may be due to the higher sensitivity of the recombinant vaccinia virus expression system. Taken together with the general finding that the Cbl 1-655 truncation mutant is not appreciably tyrosine-phosphorylated (Refs. 34 and 41 and data not shown), we tentatively conclude that there is at least one other tyrosine in the C-terminal (amino acids 655-906) region that shows increased basal and activation-induced phosphorylation in 70Z versus wt Cbl.

The molecular mechanisms underlying 70Z Cbl-induced transformation and NFAT/AP1 activation have not been previously identified. In theory, the 70Z Cbl oncoprotein may itself act as a positive signal transducer or, alternatively, it may inhibit a negative regulator that prevents or down-regulates an activating signal. Consistent with the former possibility, several groups have previously suggested that 70Z Cbl-induced transformation may, at least in part, be due to its increased phosphotyrosine content and association with Crk(L) adapter proteins (1, 28-30), perhaps through regulation of Ras signaling via the C3G-Rap1-Ras pathway. Indeed, our initial results demonstrated increased basal and activation-induced association of 70Z Cbl with Crk(L) and p85 PI3K adapter proteins. However, neither increased association of Crk(L) and p85 PI3K adapter proteins with 70Z relative to wt Cbl nor disruption of Crk(L)/p85 PI3K association with wt or 70Z Cbl detectably affects basal or anti-CD3-induced Erk1/2 activation. Consistent with these findings, Thien and Langdon (30) have been unable to detect an effect of 70Z Cbl overexpression on Erk activation in fibroblasts. As Ras activation is both necessary and sufficient to activate Erk (Ref. 39 and references therein), these findings suggest that the Cbl-Crk(L) and Cbl-p85 PI3K interactions do not affect Ras signaling. Moreover, our study clearly demonstrates that the 70Z Cbl oncoprotein retains its ability to activate NFAT and AP1 in the absence of Crk(L) and p85 PI3K binding, indicating that 70Z-induced NFAT/AP1 activation is not mediated through increased association with these adapter molecules.

Although we can exclude the possibility that 70Z Cbl-mediated NFAT activation is mediated through increased phosphorylation of Tyr-700, Tyr-731, and Tyr-774, our findings demonstrate increased phosphorylation of 70Z Cbl on additional tyrosine residues. Therefore, it remains possible that increased tyrosine phosphorylation of 70Z Cbl on these additional tyrosine residues contributes to its oncogenic and NFAT/AP1 activating properties. Our finding that 70Z Cbl requires its PTB domain for induction of NFAT and AP1 is consistent with the model that mutation of the Ring finger domain of 70Z Cbl activates or exposes its N-terminal PTB domain, which would allow increased recruitment to activated protein-tyrosine kinases. Although it is not known whether the reported enhanced association of 70Z Cbl with the epidermal growth factor and platelet-derived growth factor receptor tyrosine kinases (27, 28) depends on its PTB domain, introduction of the G306E mutation into c/v-Cbl abrogates its association with activated (receptor) tyrosine kinases in vivo as well as its transforming activity in vitro (4, 5, 27, 28). Indeed, our findings also demonstrate that the G306E mutation blocks increased tyrosine phosphorylation of 70Z Cbl, suggesting that increased tyrosine phosphorylation of 70Z Cbl results from increased or prolonged recruitment to activated tyrosine kinases via its PTB domain. Considering this model, however, it seems paradoxical that the PTB domain of Cbl associates with phosphotyrosine residue 292 of ZAP70 both in vitro and in vivo (4, 5), as mutation of this tyrosine residue disrupts interaction with the Cbl PTB domain (5) yet up-regulates NFAT activation in unstimulated Jurkat T cells (42).

As discussed above, 70Z Cbl-induced transformation and NFAT/AP1 activation may also result from inhibition of a negative regulator that prevents or down-regulates an activating signal. As studies in D. melanogaster (11), C. elegans (12), and mammalian RBL 2H3 mast cells (26) indicate that Cbl functions as an evolutionary conserved negative regulator of protein-tyrosine kinases, it is possible that 70Z Cbl acts as a dominant negative by blocking the negative regulatory role of endogenous Cbl on protein-tyrosine kinase signaling pathways. Significantly, c/v-Cbl has previously been proposed to act as a dominant negative by competing with endogenous Cbl for phosphotyrosine binding sites on activated (receptor) tyrosine kinases (27, 30). Most important, our study demonstrates that 70Z Cbl-induced NFAT/AP1 activation in unstimulated Jurkat T cells is completely blocked by the G306E mutation. This observation is consistent with a dominant negative effect of 70Z Cbl on the evolutionary conserved PTB domain-dependent negative regulatory role of endogenous Cbl on protein-tyrosine kinase signaling pathways. In this model, the increased tyrosine phosphorylation of 70Z Cbl, which depends on its PTB domain, may be the consequence of increased recruitment to an activated tyrosine kinase via its PTB domain and/or the inability of endogenous Cbl to inhibit or down-regulate activated protein-tyrosine kinases in the presence of the 70Z Cbl PTB domain. Importantly, competitive inhibition of endogenous Cbl binding to the ZAP70 phosphotyrosine residue 292 by the 70Z Cbl PTB domain is consistent with a negative regulatory role for the interaction of endogenous Cbl with the ZAP70 Tyr-292 residue (4, 5, 42). Whether wt or 70Z Cbl interacts with ZAP70 following T cell receptor activation and whether such an interaction plays any biologically significant role in T cell receptor signal transduction remains to be determined. If this model is correct, then it remains to be determined why 70Z Cbl, but not v-Cbl, is able to activate NFAT in Jurkat T cells and up-regulate epidermal growth factor receptor kinase activity in fibroblasts.

In summary, we have determined the molecular basis for NFAT and AP1 induction by oncogenic 70Z Cbl in unstimulated Jurkat T cells. Our results demonstrate that NFAT/AP1 activation by 70Z Cbl is not mediated through increased interaction with Crk(L) and p85 PI3K adapter proteins but instead depends on an intact PTB domain. These findings are most consistent with a dominant negative action of the 70Z Cbl PTB domain on the negative regulatory role of endogenous Cbl on protein-tyrosine kinases.

    ACKNOWLEDGEMENTS

We thank M. Matsuda, Gerald R. Crabtree, and Wallace Y. Langdon for generous gifts of constructs; Debby Burshtyn and Barbara L. Rellahan for advice on the use of the recombinant vaccinia virus expression system and the SEAP reporter gene assays, respectively; David Wassarman for sequencing; and Weiguo Zhang, Juan Bonifacino, and Ron Wange for critical reading of the manuscript.

    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger Recipient of a postdoctoral fellowship award from the Cancer Research Institute. To whom correspondence should be addressed: Cell Biology and Metabolism Branch, NICHD, National Institutes of Health, 9000 Rockville Pike, Bethesda, MD 20892. Tel.: 301-496-4039; Fax: 301-402-0078; E-mail: vanleeuj{at}box-v.nih.gov.

    ABBREVIATIONS

The abbreviations used are: PTB, phosphotyrosine binding; PI3K, phosphatidylinositol 3-kinase; SH3, Src homology 3; FBS, fetal bovine serum; Ab, antibody; mAb, monoclonal antibody; PAGE, polyacrylamide gel electrophoresis; SEAP, secreted alkaline phosphatase; PMA, phorbol 12-myristate 13-acetate; HA, hemagglutinin; wt, wild-type; NFAT, nuclear factor of activated T cells; AP1, activating protein 1.

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Abstract
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