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Activation of p21-Activated Kinase 1-Nuclear Factor B Signaling by Kaposi’s Sarcoma-Associated Herpes Virus G Protein-Coupled Receptor during Cellular Transformation

¹ Department of Pharmacology, University of Pennsylvania, School of Medicine, Philadelphia, Pennsylvania, and
² Division of Basic Science, Fox Chase Cancer Center, Philadelphia, Pennsylvania

	ABSTRACT

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Kaposi’s sarcoma-associated herpes virus (KSHV) contributes to the pathogenesis of Kaposi’s sarcoma and primary effusion lymphomas. KSHV encodes a G protein-coupled receptor (KSHV-GPCR) that signals constitutively and transforms NIH3T3 cells. Here, we show that KSHV-GPCR transformation requires activation of the small G protein Rac1 and its effector, the p21-activated kinase 1 (Pak1). Either transient or sustained expression of KSHV-GPCR activated both Rac1 and Pak1. Furthermore, expression of dominant-negative mutants of Rac (RacN17) or Pak1 (PakR299, Pak-PID) inhibited KSHV-GPCR-induced focus formation and growth in soft agar. We also demonstrate that signaling from Pak1 to nuclear factor-B (NFB) is required for cell transformation induced by KSHV-GPCR. KSHV-GPCR induced transcriptional activation by NFB. This process is inhibited by the PAK-PID, whereas reciprocally, expression of constitutively active Pak1 (PakL107F) activated NFB comparably to KSHV-GPCR. The Pak-PID and RacN17 inhibited the KSHV-GPCR-induced phosphorylation of inhibitor of B kinase-ß and inhibitor of B-, implying that it is Pak1-dependent phosphorylation and subsequent destruction of the inhibitor of B proteins that allows NFB activation. Finally, experiments with the KSHV-GPCR inverse agonist interferon--inducible protein-10, the G_i inhibitor pertussis toxin, and an inhibitor of phosphatidylinositol 3'-kinase, wortmannin, indicate that signaling through the G_i pathway and phosphatidylinositol 3'-kinase contributes to the cell transformation and NFB activation induced by the KSHV-GPCR.

	INTRODUCTION

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The Kaposi’s sarcoma-associated herpes virus (KSHV) is a -2 herpes virus that is implicated in the pathogenesis of malignancies including Kaposi’s sarcoma (KS), primary effusion B-cell lymphomas, and multicentric Castleman’s disease (1, 2, 3) . KS lesions are composed of diverse cell types, including infiltrating inflammatory cells, endothelial cells, and fusiform or spindle-shaped cells (4) . The pathogenic mechanisms by which infection with KSHV leads to disease are still unclear. KSHV encodes several viral oncogenes, one of which, a chemokine-like G protein-coupled receptor (KSHV-GPCR), has been strongly implicated in KS-mediated pathogenesis (5) . The KSHV-GPCR transforms rodent fibroblast cells, causes tumors in nude mice, and stimulates angiogenesis by inducing expression and secretion of vascular endothelial growth factor (VEGF; Refs. 5, 6, 7 ). Transgenic mice expressing the KSHV-GPCR develop highly vascularized KS-like tumors, further supporting the contribution of the KSHV-GPCR to the pathogenesis of KS. Expression of the KSHV-GPCR activates a number of signal-transducing pathways (6) , but the relevance of these pathways to KSHV-GPCR transformation is still poorly understood.

KSHV-GPCR is a member of the CXC chemokine G protein-linked receptor family, with significant homology to the CXCR2 receptor for IL-8 (8) . In contrast to the ligand dependence of many other GPCRs, including other CXC chemokine receptors, the KSHV-GPCR signals constitutively in a ligand-independent manner (7) . Most chemokine receptors signal primarily through the G_i pathway (9) . In contrast, KSHV-GPCR predominantly initiates a G_q signaling pathway to activate phospholipase C, thus increasing phosphatidyl-inositol turnover (7 , 10 , 11) . KSHV-GPCR also activates the major mitogen-activated protein kinase (MAPK) pathways, including notably extracellular signal-regulated kinase (ERK) signaling, and has been recently shown to activate transcription of nuclear factor B (NFB; Refs. 12, 13, 14, 15, 16 ). However, a detailed knowledge of the signaling pathways leading from the KSHV-GPCR to the activation of these downstream signaling effectors still remains elusive.

The NFB transcription factor is critically involved in cellular growth and transformation (17, 18, 19, 20, 21) , making its activation by the KSHV-GPCR of particular interest. In the absence of activation, NFB is retained in the cytoplasm due to a heterodimeric interaction with an inhibitory protein known as the inhibitor of B (IB; Refs. 22, 23, 24, 25 ). Destruction of IB is required for the activation and nuclear translocation of NFB and the subsequent transactivation of NFB target genes. Phosphorylation of IB on serine 32 and serine 36 by the IB kinases inhibitor of IB kinase (IKK) and IKKß is an important initiation signal for IB degradation and NFB release (26 , 27) . Based on knockout studies in mice, IKKß appears to be more important than IKK for controlling NFB activity in response to cytokines and other ligands (28) . NFB activation stimulates both cell survival and cell proliferation, and NFB signaling has been shown to be essential for oncogenes such as Ras and Raf to transform cells (29) .

Consideration of known signaling pathways controlled by the oncoprotein Ras provides a useful context for the analysis of KSHV-GPCR control of NF-B and the relevance of this control pathway to KSHV-GPCR-dependent cell transformation. Ras and its effectors, including the Rho family GTPases Rac1 and Cdc42, induce the phosphorylation of serine 32 and serine 36 of IB and cause the ubiquitination of the IB complex, which releases the IB-bound NFB to translocate to the nucleus (30) . Rac1 and Cdc42 share several downstream effectors, including the p21-activated kinase 1 (Pak1; Ref. 31 ). Pak1 mediates Rac1/Cdc42-stimulated cytoskeletal signals (32) and has also been show to play a critical role in the control of cell survival, cell proliferation, and cell transformation by oncogenes including Ras (33) . In many different cell types, Pak1 regulates the ERK cascade. It may also regulate p38 and c-Jun NH₂-terminal kinase signaling, but this signal, unlike the ERK signal, is probably not important for anchorage-dependent cell growth and survival (34 , 35) . Significantly, recent studies have shown that Ras also requires Pak1 to activate NFB (36 , 37) .

Like Ras, GPCRs are dependent on Rho GTPase-controlled signaling pathways (38) . Several GPCRs, such as Mas, G2A, and PAR-1, mediate cell transformation through the Rho family proteins Rac1 and RhoA (39 , 40) . In this work, we demonstrate KSHV-GPCR activation of Rac1 and Pak1 and show that Pak1 is essential for KSHV-GPCR-induced anchorage-dependent growth. We additionally show that the activation of NFB by KSHV-GPCR proceeds through Pak1-induced phosphorylation of IKKß, and we demonstrate that NFB activation is also essential for KSHV-GPCR-mediated cell transformation. Our work thus provides direct evidence for an important role for Pak1 as a downstream signaling molecule involved in the KSHV-GPCR to NFB cell transformation pathway.

	MATERIALS AND METHODS

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Plasmids.
cDNA expression plasmids using the CMV promoter to express myc-tagged Pak1, PakR299, and RacN17 based on the plasmid pCMV6M (a modified version of pCMV5) have been described elsewhere (41) . The pCMV6M-PakL107F and pEBG-PIDL107F expression plasmids were a kind gift from J. Chernoff (Fox Chase Cancer Center, Philadelphia, PA).³ Mutating leucine 107 to phenylalanine leads to strong activation of full-length Pak1, and this activity is independent of the Rac1 and Cdc42 GTPases (42) , even though binding to these proteins is maintained. The 83–149-amino acid fragment of Pak1, termed the Pak inhibition domain (PID), inhibits autophosphorylation and substrate phosphorylation, whereas the L107F mutated fragment is strongly reduced in its inhibitory potency (42) . To generate the pCMV6M-Pak-PID construct, the PID (amino acids 83–149) of human wild-type Pak1 was amplified from wild-type Pak1 cDNA by PCR as a BamHI-EcoRI insert using 5'-CGCCGCGGATCCCACACAATTCATGTCGGTTTTGATGC-3' and 5'-CGCCGCGAATTCTGACTTATCTGTAAAGCTCATGTATTTCTGGC-3' as primers and subcloned into the pCMV6M vector. The pCEFL-AU5-KSHV-GPCR expression plasmid was a gift from S. Gutkind (NIH, Bethesda, MD; Ref. 10 ). The pZIP-NeoSV (x) 1-Human K-Ras4B expression plasmid was a gift from C. Der (University of North Carolina, Chapel Hill, NC; Ref. 43 ). The pNFB-Luc reporter plasmid containing five copies of the enhancer element of NFB (TGGGGACTTTCCGC) and the pTK-Luc reporter plasmid were a gift from D. Manning (University of Pennsylvania, Philadelphia, PA; Ref. 44 ). The pCMV-IBM and pEGFP-C4 plasmids were purchased from BD Biosciences Clontech (Palo Alto, CA).

Reagents.
Pertussis toxin (PTX), human IFN--inducible protein-10 (IP-10), and wortmannin were purchased from Sigma-Aldrich (St. Louis, MO). Human monokine induced by IFN- (MIG) was purchased from PharMingen (Palo Alto, CA), and the inhibitors BAY-11-7082, LY294002, PD98059, and U0186 were purchased from Calbiochem (La Jolla, CA). Monoclonal antibodies (MAbs) against Ras, Rac1, and Cdc42 were purchased from Transduction Lab (Carlsbad, CA). The AU5 MAb against the AU5-tag on KSHV-GPCR was purchased from Research Diagnostics, Inc. (Flanders, NJ), and the anti-myc-tag MAb 9E10 was purchased from Calbiochem. The polyclonal antibodies against Pak1 (N-20), Pak2, and Pak3 were purchased from Santa Cruz Biotechnology Lab (Santa Cruz, CA). All other antibodies were purchased from Cell Signaling Technology, Inc. (Beverly, MA). Recombinant human tumor necrosis factor- (TNF-) was purchased from R&D Systems, Inc. (Minneapolis, MN).

Cell Culture and Stable Cell Lines.
NIH3T3 and Rat-1 cells were grown at 37°C in 5% CO₂, 95% air in high-glucose (4.5 g/liter) DMEM purchased from Fisher Scientific (Pittsburgh, PA), supplemented with 10% fetal bovine serum, penicillin (100 U/ml), and streptomycin (100 µg/ml). To establish stable cell lines expressing KSHV-GPCR, the pCEFL-AU5-KSHV-GPCR plasmid was transfected into NIH3T3 cells using LipofectAMINE Plus reagent (Life Technologies, Inc., Carlsbad, CA) according to the manufacturer’s protocol. Forty-eight h after the addition of DNA, the transfected cells were selected in growth medium containing 1 mg/ml Geneticin (G418; Life Technologies, Inc., Grand Island, NY). Protein expression levels were determined by Western blot analysis of G418-selected cell lysates using the anti-AU5 for cells expressing KSHV-GPCR. Blots were visualized with the procedure outlined in the enhanced chemiluminescence kit from Amersham Biosciences (Piscataway, NJ). The K-Ras-transformed stable cell line has been described elsewhere (35) .

Transient Transfections and Western Blotting.
NIH3T3 cells were transfected with plasmids specified in "Results" together with pEGFP-C4 plasmid DNA expressing the green fluorescence protein (GFP) at a ratio of 10:1, using LipofectAMINE Plus according to the manufacturer’s protocol. Transfection efficiency was assayed by checking for green fluorescence of the GFP protein under a Nikon N6000 fluorescence microscope and was typically 75–90%. Forty-eight h post-transfection, cell lysates were prepared by washing cells with cold PBS followed by lysis in 1x lysis buffer containing 40 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (pH 7.4), 1% NP40, 100 mM NaCl, 1 mM EDTA, 25 mM NaF, 1 mM sodium orthovanadate, 10 µg/ml leupeptin, and 10 µg/ml aprotinin. Samples were centrifuged at 12,000 x g for 10 min at 4°C, and the supernatants were collected. Western blot analysis using appropriate antibody was done using 50 µg of the total cell lysate.

Transformation Assays.
NIH3T3 and Rat-1 cells were transfected as described above. Forty-eight h post-transfection, cells were split 1:5 into 100-mm-diameter dishes. The cells were refed twice a week with fresh growth medium. Cell foci were scored 14–18 days post-transfection by fixing the cells in a 10% acetic acid:10% methanol solution and staining the dishes with 0.4% crystal violet in 10% ethanol. Soft agar assays were performed as described previously (45) . In brief, after transfection, cells (10⁵) were plated on 60-mm dishes. After 21–24 days, colonies were scored by inspection under a Nikon DIAPhot microscope using phase contrast and also after staining the dishes with 0.5 mg/ml 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (Sigma-Aldrich) overnight at 37°C. For drug inhibition assays, the soft agar assay was done as described previously (46) . In brief, transfected cells were suspended in DMEM containing 0.41% Bacto agar supplemented with 10% fetal bovine serum, in the presence or absence of specific inhibitors (10 nM wortmannin, 25 µM PD98059, 25 µM U0126, 5 mg/ml PTX, 10 mM IP-10, 10 mM MIG, and 5 mg/ml BAY-11-7082). The cell suspension was then overlaid onto a hard agar base composed of DMEM containing 0.72% Bacto agar supplemented with fetal bovine serum in 60-mm plates. Fetal bovine serum (10%)-DMEM with or without the specific inhibitor was added every 3 days to the plates. For wortmannin, which has a short half-life, medium with the drug was added every 8 h. The colonies were scored after 15 days as described above.

Rac1 and Cdc42 Activation Assays.
NIH3T3 cells were transfected with plasmid-expressing KSHV-GPCR or vector only for either transient or stable expression, and cells were lysed as described above. Small aliquots (20 µg) of lysate were removed for determination of Rac1 and Cdc42 expression by Western blotting. The remainder of the lysate (250 µg) was incubated with glutathione S-transferase (GST) or GST-Pak-binding domain (GST-PBD; a gift from Dr. Chernoff) and glutathione-Sepharose 4B beads (Upstate Biotechnology, Inc., Lake Placid, NY) at 4°C for 1 h (47) . The beads were washed three times with 1x lysis buffer and pelleted. Pelleted activated Rac1 bound to GST-PBD and total Rac1 within the lysates was detected by Western blotting using a MAb against Rac1. The blots were then stripped using Restore Western blot stripping buffer (Pierce, Rockford, IL) and reprobed for activated Cdc42 and total Cdc42 protein expression using anti-Cdc42 MAb. To obtain a Rac1 activation profile, NIH3T3 cells expressing the vector alone were cultured with medium containing no serum for 16 h; treated for 0, 2.5, 5, or 10 min with insulin (100 nM); lysed; and assayed for Rac1 activation using the GST-PBD Sepharose beads.

For experiments with the inhibitory compounds, PTX (500 µg/ml), human IP-10 (100 nM), and human MIG (100 nM) cells expressing sustained KSHV-GPCR were cultured with medium containing no serum for 16 h; treated with the above compounds for 3 h; lysed; and analyzed for the presence of activated Rac1 and Pak1. Phosphorylation status of IB and IKK was also determined (see protocol below).

Pak1 Kinase Assays.
Exogenous Pak1 was immunoprecipitated from lysates of NIH3T3 cells transfected with a construct expressing myc-tagged Pak1 by incubation with anti-myc antibody and protein A-agarose for 2 h at 4°C (35) . Samples were incubated for 30 min at 4°C, washed three times with 1x lysis buffer and twice with 2x phosphorylation buffer [10 mM MgCl₂, 40 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (pH 7.4)], and then incubated with 5 µg of myelin basic protein (Sigma-Aldrich) for 5 min on ice. Kinase assays were initiated by the addition of 10 µCi of [-³²P]ATP (3,000 Ci/mmol) and 20 µM (final concentration) ATP, followed by incubation for 10 min at 22°C. Reactions were stopped by the addition of 2x SDS sample buffer and heating to 95°C. Reaction products were resolved by 12.5% SDS-PAGE and visualized by autoradiography.

To measure endogenous Pak1 activity, NIH3T3 cells were transfected with the appropriate plasmids as described above. The cells were incubated for 24 h to allow protein expression and then serum starved for 16–18 h before lysing. Pak1 was immunoprecipitated from 500 µg of cell lysate by incubating with 2 µg of rabbit anti-Pak antibody (N-20) and protein A-Sepharose for at least 2 h at 4°C on a rotating platform. The immunoprecipitates were pelleted by centrifugation and washed three times with 1x lysis buffer. The immunoprecipitated Pak1 was solubilized with 2x SDS sample buffer, subjected to 12.5% SDS-PAGE, and transferred to nitrocellulose. Phosphorylated Pak1 activity was detected by using phosphospecific Pak1 antibody directed against threonine 423 of wild-type Pak1. Total Pak1 was detected by Western blotting using rabbit polyclonal anti-Pak1 antibody (N-20).

Electrophoretic Mobility Shift Assay (EMSA).
EMSAs were performed using a EMSA "Gel-Shift" kit from Panomics, Inc. (Redwood City, CA). In brief, 100-mm dishes of NIH3T3 stable cell lines expressing vector alone or KSHV-GPCR were starved overnight, along with stable KSHV-GPCR cell-line transiently transfected with plasmids expressing RacN17, Pak-PID, and PIDL107F. Nuclear extracts were prepared the following day using the manufacturer’s protocol for the Panomics nuclear extraction kit. The nuclear extracts were then incubated with a biotin-tagged NFB probe (5'-AGTTGAGGGGACTTTCCCAGGC) along with nonspecific and specific competitors supplied with the kit where indicated for 30 min at 15°C, according to the manufacturer’s protocol. The extracts were electrophoresed using a 5% polyacrylamide gel at 4°C and transferred to S&S NYTRAN nylon membrane (Schleicher & Schuell, Keene, NH). The blots were developed using the detection kit provided in the EMSA kit and visualized with an enhanced chemiluminescence detection system (Amersham Biosciences).

Reporter Gene Assays.
For measurements of NFB reporter gene activity, NIH3T3 cell lines stably expressing either vector or KSHV-GPCR or K-Ras were transfected with the cis-reporter plasmid NFB-Luc (Stratagene, La Jolla, CA), which contains a NFB-driven firefly luciferase gene, together with pTK-Luc (Promega, Madison, WI), which contains the Renilla luciferase gene under control of the herpes simplex virus thymidine kinase promoter (44) . Twenty-four h post-transfection, cells were washed with ice-cold PBS and lysed for measurement of luciferase activities using reagents of the Dual-Luciferase Reporter Assay System (Promega). Measurements were performed with a Turner Designs (Sunnyvale, CA) luminometer using a 10-s setting. Firefly luciferase activities were normalized to Renilla luciferase activities. For experiments with the Pak-PID, the stable KSHV-GPCR and K-Ras cell lines were transfected with Pak-PID along with the luciferase reporter plasmids, and 24 h post-transfection, cells were lysed and assayed for NFB activity. For experiments with the inhibitory compounds BAY-11-7082 (5 ng/ml), wortmannin (10 nM), PD98059 (30 µM), U0186 (30 µM), and PTX (500 µg/ml), KSHV-GPCR and K-Ras stable cell lines were treated for 30 min with these compounds 24 h after transfection with the luciferase reporter plasmids, lysed, and analyzed for NFB activity. For experiments with human TNF-, cells were treated with 30 ng/ml human TNF- for 40 min, lysed, and analyzed for NFB activity.

IB and IKK Phosphorylation Assays.
NIH3T3 cells stably expressing KSHV-GPCR were transiently transfected with either the dominant-negative RacN17 or Pak-PID plasmids along with pEGFP-C4 plasmid as described above. Twenty-four h after transfection, the cells were serum starved for another 24 h and then lysed. Fifty µg of total cell lysate were used for immunoblotting using phosphospecific antibodies against IB and IKK.

Quantification of Data and Statistical Analysis.
To quantitate data, for Western analysis, densitometric analysis of the enhanced chemiluminescence-exposed blots was done using the NIH ImageJ (version 1.24o) software. For Pak1 kinase assays, the relative levels of myelin basic protein phosphorylation were quantitated based on direct analysis of radioactive signal using a Storm 840 PhosphorImager (Molecular Dynamics, Carlsbad, CA) and IO software version 2.

Statistical differences between different groups were determined using the ANOVA and Tukey-Kramer multiple comparisons test for significance. The data are presented as mean ± SE for at least three separate determinations for each treatment.

	RESULTS

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A Role for Rac1 and Pak1 in KSHV-GPCR-Mediated Cell Transformation.
We hypothesized that KSHV-GPCR transformation of NIH3T3 cells involves the Pak1 signaling cascade. To evaluate the role of Pak1 and its activation by Rac1 in KSHV-GPCR-induced cell transformation, we transfected NIH3T3 and Rat1 fibroblast cells with KSHV-GPCR by itself or with a set of Rac1 and Pak1 derivatives. These included (a) wild-type Pak1 (Pak1); (b) constitutively active Pak1 (PakL107F; this mutation interrupts an intramolecular Pak1 interaction responsible for Pak inactivation; Ref. 42 ); (c) a kinase dead Pak1 that functions as a dominant negative (PakR299; Ref. 48 ); (d) a PID truncation of Pak1 that also functions as a dominant negative (Pak-PID, containing amino acids 83–149 of Pak1; Ref. 42 ); (e) a Pak-PID with an inserted L107F mutation, which eliminates its dominant-negative function (PID-L107F); and (f) a dominant-negative Rac1, which prevents activation of Pak1 (RacN17; Ref. 41 ). For comparison, we also transformed cells with constitutively active PakL107F by itself.

We measured transformation by assessing growth on soft agar. Plates transfected with KSHV-GPCR alone had 150 colonies, a 30-fold increase over plates transfected with vector (Fig. 1, A and B) . KSHV-GPCR-dependent colony formation was strikingly inhibited by all plasmids expressing proteins that inhibited Pak1 activation, with a reduction of 92% (RacN17), 84% (PakR299), and 89% (Pak-PID) observed (Fig. 1B) . The specificity of the inhibitory effect was further confirmed by the fact that the PID-L107F derivative did not inhibit KSHV-GPCR transformation (Fig. 1B , contrast Lanes 6 and 7). Finally, coexpression of the constitutively activated PakL107F with KSHV-GPCR resulted in a minor increase in transformation efficiency versus the KSHV-GPCR alone (Fig. 1B , Lanes 2 and 3), whereas transformation with PakL107F alone resulted in induction of colonies almost equivalent to that seen with the KSHV-GPCR (Fig. 1B , Lanes 2 and 8). These results are compatible with the idea that endogenous levels of Pak1 are sufficient to mediate KSHV-GPCR signaling for transformation. They also suggest that a substantial portion of KSHV-GPCR signaling proceeds through Pak1 and involves full activation of Pak1, such that activation of Pak1 by other (e.g., mutational) means does little to augment KSHV-GPCR transformation.

View larger version (58K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Role of Pak1 in KSHV-GPCR-induced cell transformation. A and B, soft agar assays. NIH3T3 cells transfected with vector or KSHV, and where indicated, Pak constructs were allowed to grow in soft agar and then stained with 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide for visualization of colonies as described in "Materials and Methods." A, colonies stained with 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide. B, the data are presented as mean of the number of colonies per plate ± SE from three independent experiments. *, significant increase in formation of colonies (p < 0.001). C, focus formation assays. Cells were transfected with constructs as listed and stained with crystal violet to visualize foci as described in "Materials and Methods." The data are presented as mean of the number of foci per plate ± SE from five independent experiments. *, significant increase in formation of foci (p < 0.001).

Separately, NIH3T3 cells transfected as described above with a subset of the described constructs were also cultured for 14–18 days to assess the dependence of focus formation on the Pak1 signaling pathway. In the plates transfected with KSHV-GPCR alone, 60–75 foci developed versus 6 foci in NIH3T3 cells transfected with vector (Fig. 1C) . Notably, cotransfection of the dominant negatives PakR299 or Pak-PID with KSHV-GPCR significantly reduced the number of foci observed (77 and 81% fewer foci, respectively) whereas PID-L107F had no effect. In contrast, cotransfection of constitutively active Pak1 enhanced transformation only a small degree over KSHV-GPCR alone (Fig. 1C) . These results were in agreement with the soft agar studies.

KSHV-GPCR activates Rac1, Cdc42, and Pak1.
If KSHV-GPCR activation of a Pak signaling cascade is required for KSHV-GPCR induction of cell transformation, we note three different Pak1 family members (Pak1, Pak2, and Pak3) with highly related amino acid sequences and overlapping signaling function have been described previously (32) , and each may potentially be a KSHV-GPCR target. We directly assessed expression of these three forms of Pak in NIH3T3 cells and, for contrast, in Rat1 cells (Fig. 2A) . Antibody to Pak1 yielded a strong signal in both cell types; Pak2 was abundant in Rat1 cells but not NIH3T3 cells; and Pak3 was poorly detected in both cell types, suggesting limited expression of Pak3. Based on these results, we conclude that the predominant isoform of Pak expressed in NIH3T3 cells is Pak1, with very low levels of Pak2 and Pak3. Hence, we concentrated the rest of our studies on the Pak1 isoform.

View larger version (23K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. A, endogenous levels of the Pak isoforms in NIH3T3 cells. Rat-1 and NIH3T3 cell lysates were probed with anti-Pak1, anti-Pak2, and anti-Pak3 antibodies. B, activation of Rac1 by transient expression of KSHV-GPCR. NIH3T3 cells were transfected with either vector or KSHV-GPCR along with pEGFP-C4-expressing plasmid. All cell populations were 90% GFP positive as observed under a fluorescence microscope. Activated Rac1 and Cdc42 in total cell lysates was pulled down using either GST-PBD or GST and glutathione-Sepharose beads and then probed with antibody to Rac1 and Cdc42, respectively. Panel 1 shows the presence of activated Rac1 and Cdc42 bound to GST-PBD or GST, and panel 2 shows the total Rac1, Cdc42, and KSHV-GPCR present in the whole-cell lysate (WCL). The expression of transfected KSHV-GPCR in the cell lysate was probed with anti-AU5 antibody against the AU5-tag on KSHV-GPCR. Similar results were obtained in three independent experiments, and a representative blot is shown. C, activation of Pak1 by transient expression of KSHV-GPCR. NIH3T3 cells were transfected with Pak1 and either vector- or KSHV-GPCR-expressing plasmids along with pEGFP-C4. Transfection efficiency was confirmed as being 90% by observing for green fluorescence emitted by GFP protein under a fluorescence microscope. Top panel, Pak1 phosphorylation activity was measured in a kinase assay with myelin basic protein as a substrate. Bottom panel, expression of total Pak1 in the cell lysate. Fold, fold increase in substrate phosphorylation over that occurring in the vector lane determined as described in "Materials and Methods." Similar results were obtained in three independent experiments, and a representative autoradiogram is shown. D, dominant-negative RacN17 and Pak-PID inhibit KSHV-GPCR activation of endogenous Pak1. NIH3T3 cells were transfected with HA-RacN17, myc-Pak-PID, and vector or KSHV-GPCR along with pEGFP-C4-expressing plasmids as shown. Transfection efficiency was confirmed to be 90% as observed by fluorescence microscope. The cell extract was immunoprecipitated with anti-Pak1 (N-20) antibody and then probed with phosphoPak (threonine 423) antibody. Total cell lysate was probed with anti-Pak1 (N20) antibody, anti-HA antibody, 9E10 antibody, and anti-AU5 antibody, which recognize the endogenous Pak1, the HA-tag on RacN17, the myc-tag on Pak-PID, and the AU5-tag on KSHV-GPCR, respectively. Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold activation of Pak1 over that occurring in the vector lane determined as described in "Materials and Methods."

We next examined the KSHV-GPCR activation of Pak1. Because endogenous levels of Pak1 are too low to permit analysis of activation status, NIH3T3 cells were cotransfected with Pak1 along with KSHV-GPCR or vector. Forty-eight h after transfection, Pak1 was immunoprecipitated and tested for its activation status. KSHV-GPCR stimulated activation of Pak1, as detected by Pak1 phosphorylation of myelin basic protein substrate, about 16-fold over the over basal levels (Fig. 2C) . To determine whether Rac1 was required to mediate the signal from KSHV-GPCR to Pak1, we assessed whether RacN17 or the Pak-PID inhibited activation of Pak1 by KSHV-GPCR. Cells were transfected with Pak1 and with vector or KSHV-GPCR alone or KSHV-GPCR with either RacN17 or the Pak-PID. Although an anti-Pak1 immunoprecipitate from KSHV-GPCR-expressing cells had a substantial amount of activated Pak1 phosphorylated at threonine 423, the immunoprecipitates from cells cotransfected with RacN17 or the Pak-PID construct showed about 11-fold less phosphorylated Pak1, reduced to basal uninduced levels (Fig. 2D) . Together, these results indicated that efficient KSHV-GPCR activation of Pak1 requires Rac1.

Development of a Stable Cell Line System to Analyze KSHV-GPCR Transformation.
To facilitate detailed analysis of KSHV-GPCR cell transformation, stable cell lines were developed in the NIH3T3 background that expressed parental vector or KSHV-GPCR (Fig. 3A) . As preliminary characterization, the cell lines were tested in cell transformation assays as described above, using both focus formation and soft agar colony assays. The stable cell lines formed both foci and colonies, which could be inhibited by cotransfection with PakR299, Pak-PID, and RacN17, similar to the transiently transfected NIH3T3 cells (data not shown). Stable expression of KSHV-GPCR in these cell lines activated both Rac1 and Pak1, similar to transient expression of KSHV-GPCR (Fig. 3, B and C, Lanes 1 and 2 in each). We then used these NIH3T3 stable cell lines to perform a series of experiments to study the signals from KSHV-GPCR through Pak1.

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. A, characterization of NIH3T3 stable cell line expressing KSHV-GPCR. KSHV-GPCR levels in stable NIH3T3 cells expressing KSHV-GPCR was analyzed by probing with anti-AU5 antibody. B, activation of Rac1 by sustained KSHV-GPCR signaling. Rac1 activity was assayed in stable NIH3T3 cells expressing vector alone or KSHV-GPCR. KSHV-GPCR-expressing cells were pretreated with the Gi protein inhibitor PTX, the KSHV-GPCR inverse agonist IP-10, and MIG, a CXC3 ligand belonging to the same family as IP-10 for 3 h and lysed; and activated Rac1 was pulled down as described in "Materials and Methods" and probed with anti-Rac MAb. Top panel, activated Rac1 pulled down by GST-PBD bound to Sepharose beads. Bottom panel, total Rac1 in the whole-cell lysate (WCL). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold activation of Rac1 over that occurring in the vector lane determined as described in "Materials and Methods." C, activation of Pak1 by sustained KSHV-GPCR signaling. Pak1 activity was assayed in stable NIH3T3 cells transfected either with vector alone or with KSHV-GPCR. KSHV-GPCR-expressing cells were pretreated with the Gi protein inhibitor PTX and the KSHV-GPCR inverse agonist IP-10 for 3 h and lysed. The cell extract was immunoprecipitated with the anti-Pak1 (N-20) antibody and then probed with phosphoPak (threonine 423) antibody (top panel). Total cell lysate was probed with anti-Pak1 (N-20) antibody (bottom panel). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold activation of Pak1 over that occurring in the vector lane determined as described in "Materials and Methods." D, transient activation of Rac1 by insulin. NIH3T3 cells expressing vector alone were stimulated with insulin for 0, 2.5, 5, and 10 min and lysed; and activated Rac1 was pulled down as described in "Materials and Methods" and probed with anti-Rac MAb. Top panel, activated Rac1 pulled down by GST-PBD bound to Sepharose beads. Bottom panel, total Rac1 in the whole-cell lysate (WCL). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold activation of Rac1 over that occurring at time point 2.5 min determined as described in "Materials and Methods."

KSHV-GPCR Cell Transformation Requires NFB.
Activation of NFB is a rapid event that occurs within minutes after stimulation and results in transcription of genes that favorably alter the cellular environment to promote cell survival and proliferation. Hence, up-regulation of NFB is a common strategy among viruses. HIV-1, HTLV-1, HBV, HCV, and herpes viruses have been shown to activate the NFB pathway (50) , whereas in some contexts, Pak1 has been shown to promote NFB activation (37) . To determine whether NFB activation is essential for KSHV-GPCR-mediated cellular transformation, we performed soft agar assays with the cells expressing KSHV-GPCR cotransfected with a dominant-negative derivative of IB. This mutant, IBM, has two serine to alanine mutations at residues 32 and 36 (the sites of IKK phosphorylation), making it resistant to degradation and thus causing a constitutive blockade of the NFB signaling pathway. As an alternative approach, we treated cells with BAY-11-7082, which specifically blocks TNF--mediated degradation of IB; whereas as a reference, we also used the IP-10 and MIG compounds tested previously for KSHV-GPCR inhibition of Pak1 and Rac1 activation (Fig. 3, B and C) . The inhibitor BAY-11-7082 or the dominant-negative IB mutant resulted in an almost total inhibition of the formation of colonies by KSHV-GPCR (Fig. 4A) to a degree even greater than that seen with the KSHV-GPCR inhibitor IP-10, whereas the negative control MIG had no effect on colony formation. These results clearly demonstrated a significant role of NFB in cell transformation induced by KSHV-GPCR.

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. A, inhibition of NFB by dominant-negative IB mutant or BAY-11-7082 inhibits anchorage-dependent growth induced by KSHV-GPCR. NIH3T3 cells expressing KSHV-GPCR were cotransfected with the IBM plasmid, plated on soft agar, and stained with 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide after 14–18 days to visualize colonies as described in "Materials and Methods." For studying the effect of BAY-11-7082, IP-10, and MIG, soft agar assay was performed in the presence of the drug. The data are presented as the mean of the number colonies per plate ± SE from three independent experiments. *, significant increase in NFB-luciferase activation (p < 0.001). B, activation of NFB by sustained KSHV-GPCR signaling. DNA-binding capacity of NFB was measured by performing EMSAs on stable NIH3T3 cells expressing vector or KSHV-GPCR alone or KSHV-GPCR cells transiently expressing either RacN17, Pak-PID, and Pak-PIDL107F or PakL107F alone as described in "Materials and Methods." EMSAs were also performed with 5x and 10x concentrations of a specific competitor (comp) and a nonspecific competitor (non-sp comp) with nuclear extract of cells expressing KSHV-GPCR. Fold, fold increase in binding of NFB to DNA over that occurring in the vector lane, determined as described in "Materials and Methods." Arrows, NFB bound to DNA probe and free probe. C, expression of KSHV-GPCR results in NFB activation that can be inhibited by Pak-PID. NIH3T3 cells expressing either vector or KSHV-GPCR (+/- BAY-11-7082) or K-Ras cotransfected with pNFB-Luc and pTK-Luc were assessed by dual luciferase assay as described in "Materials and Methods." Pak-PID, Pak-PIDL107F, and PakL107F DNA were cotransfected in NIH3T3 cells expressing either vector or KSHV-GPCR/K-Ras. Data represent the mean ± SE of five experiments performed in duplicate. *, significant increase in NFB-luciferase activation (p < 0.001).

KSHV-GPCR Activates NFB through Pak1.

As a second approach, we performed dual-luciferase assays in the stable NIH3T3 cells expressing KSHV-GPCR or vector. These cells were cotransfected with a firefly luciferase reporter plasmid under the control of the NFB promoter and a Renilla luciferase reporter plasmid under the control of thymidine kinase promoter as an internal control for transfection efficiency. As seen in Fig. 4C , a 7-fold increase in NFB activity was observed in cells expressing KSHV-GPCR versus cells with vector alone. Similarly constructed NIH3T3 cell lines expressing K-Ras, used as a positive control for NFB activation, showed a 6-fold increase in NFB activity over cells with vector alone, comparable with that seen with KSHV-GPCR. Cotransfection of the Pak-PID into these cells along with the luciferase reporters caused a 4-fold inhibition of NFB activity in the KSHV-GPCR cell line, and a 11-fold inhibition in the K-Ras cell line, to levels seen with vector alone (Fig. 4C) . Notably, transient transfection with the constitutively active Pak1 (PakL107F) alone showed a similar activation of NFB (6-fold) as cells expressing KSHV-GPCR or K-Ras (Fig. 4C) , suggesting that Pak1 acts as a primary conduit of signaling to NFB. Finally, as a control, we determined that treatment of KSHV-GPCR cell lines with the IB inhibitor BAY-11-7082 completely abolished the NFB activation by KSHV-GPCR (Fig. 4C) . Together, these data indicated that KSHV-GPCR activation of Pak1 is a major conduit of signaling to NFB.

IKKß Is Targeted by Pak1 to Regulate NFB Activation in KSHV-GPCR-Transformed Cells.
Because phosphorylation of IB is a necessary step in the activation of NFB, we examined the status of IB in cells expressing KSHV-GPCR. Of the IB and IBß proteins, IB is much more widely studied, and excellent phosphospecific anti-IB antibodies are available; hence, we focused analysis on examination of IB phosphorylation status. The total cell lysate of cells expressing either the vector or KSHV-GPCR was immunoblotted with phosphospecific antibody directed against the serine residue at position 32 of IB subunit. Cells expressing KSHV-GPCR showed a significantly increased amount of phosphorylated IB over cells expressing the vector alone (Fig. 5A) . Pretreatment of these cells with PTX or IP-10, both inhibitors of KSHV-GPCR signaling, inhibited phosphorylation of IB at serine 32 (Fig. 5A, i) , as did transfection of cells with RacN17 and the PAK-PID dominant-negative mutants of the downstream effector molecules, Rac1 and Pak1 (Fig. 5A, ii) . These results strongly support the idea that Pak1 is involved in KSHV-GPCR signaling to NFB through IB, although involvement of IBß cannot be ruled out.

View larger version (36K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. A, inhibition of IB phosphorylation is induced by KSHV-GPCR. i, inhibition of IB phosphorylation by Gi-specific inhibitor PTX and an inverse agonist of KSHV-GPCR, IP-10. NIH3T3 cells constitutively expressing KSHV-GPCR were pretreated with PTX and IP-10 as described in "Materials and Methods," lysed, and immunoblotted with antibody to IB phosphoserine 32 (top panel) and total IB expression with antibody to IB (bottom panel). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold phosphorylation of IB over that occurring in the vector lane determined as described in "Materials and Methods." ii, inhibition of IB phosphorylation by dominant-negative RacN17 and Pak-PID. IB phosphorylation was detected by analyzing lysates of stable NIH3T3 cells expressing vector or KSHV-GPCR alone, or KSHV-GPCR cells transiently expressing either RacN17 or Pak-PID. Phosphorylation was detected with antibody to IB phosphoserine 32 (top panel) and total IB expression with antibody to IB (bottom panel). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold phosphorylation of IB over that occurring in the vector lane determined as described in "Materials and Methods." B, inhibition of IKKß phosphorylation is induced by KSHV-GPCR. i, inhibition of IKKß phosphorylation by Gi-specific inhibitor PTX and an inverse agonist of KSHV-GPCR, IP-10. Stable NIH3T3 cells expressing KSHV were pretreated with PTX and IP-10 as described in "Materials and Methods," lysed, and immunoblotted with phophospecific antibody against IKKß (serine 181) and IKK (serine 180; top panel) and antibody to IKKß (serine 181) and IKK (serine 180; bottom panel). Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold phosphorylation of IKKß over that occurring in the vector lane determined as described in "Materials and Methods." ii, inhibition of IKKß phosphorylation induced by KSHV-GPCR by dominant-negative RacN17 and Pak-PID. IKK phosphorylation was detected by lysing stable NIH3T3 cells expressing vector or KSHV-GPCR alone or KSHV-GPCR cells transiently expressing either RacN17 or Pak-PID and detecting IKK phosphosphorylation with a phosphospecific antibody. The top panel was probed with phosphospecific antibody against IKKß (serine 181) and IKK (serine 180), and the bottom panel was probed for total IKK/ß protein expression. Similar results were obtained in three independent experiments, and a representative blot is shown. Fold, fold phosphorylation of IKKß over that occurring in the vector lane determined as described in "Materials and Methods." C, expression of RacN17 and Pak-PID. This panel shows the expression of RacN17 and Pak-PID in the NIH3T3 cells used in the above figures. The blots were probed with anti-HA antibody and 9E10 antibody against the HA-tag on RacN17 and myc-tag on Pak-PID.

A Contribution of Phosphatidylinositol 3'-Kinase (PI3K) to KSHV-GPCR-Mediated Activation of NFB and Exclusion of a Role for TNF-.
KSHV-GPCR activates several signaling pathways that might contribute to its ability to activate NFB either through or independent of Pak1 activation, including the MAPK [MAP/ERK kinase (MEK)/ERK] and PI3K pathways (13 , 15 , 16 , 53) . Notably, our data presented above showing PTX inhibition of KSHV-GPCR-dependent Rac1 activation suggest involvement of G_i proteins, which can signal to PI3K, in KSHV-GPCR activation of Rac1 and Pak1 (54) . To examine the contribution of these other proteins to the KSHV-GPCR to NFB cell transformation signaling pathway, we investigated the role of the pharmacological agents known to specifically inhibit the G_i, PI3K, and MAPK pathways in KSHV-GPCR-mediated cellular transformation. We did this by carrying out soft agar assays with cells expressing KSHV-GPCR treated with PTX (G), wortmannin (PI3K), PD98059, or U0126 (MEK/MAPK). We observed fewer colonies with KSHV-GPCR-expressing cells treated with wortmannin, PD98059, U0126, or PTX than the colonies formed by untreated cells expressing the KSHV-GPCR (Fig. 6A) . An inhibition of 82, 75, 68, and 76% of colony formation in soft agar was observed on treatment with PTX, wortmannin, PD98059, and U0126, respectively, indicating that both PI3K and MEK1 signaling contributed to KSHV-GPCR transformation. However, none of these levels of reduction approached those seen with inhibition of Pak1 signaling (Fig. 1 B; data not shown), excluding, for example, PI3K activation as the sole signaling conduit from KSHV-GPCR to Pak1.

View larger version (25K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. A, effect of wortmannin on the colony formation of KSHV-GPCR-transformed NIH3T3 cells. A soft agar assay was performed as described in "Materials and Methods" with or without wortmannin, PD98059, U1026, and PTX. Data represent the mean ± SE from three independent experiments. *, significant increase in formation of colonies (p < 0.001). B, involvement of PI3K in KSHV-GPCR-induced NFB activation. NIH3T3 cells expressing either vector or KSHV-GPCR/K-Ras were treated with 50 nM wortmannin, 30 µM PD98059, 30 µM U0186, and 500 µg/ml PTX for 30 min before lysing the cells. Dual luciferase assay was performed, and NFB activity was determined as described in the legend of Fig. 5A . Data represent the mean ± SE from three independent experiments performed in duplicate. *, significant increase in NFB-luciferase activation (p < 0.001). C, role of TNF- in KSHV-GPCR-induced NFB activation. NIH3T3 cells expressing either vector or KSHV-GPCR or NIH3T3 cells expressing KSHV-GPCR cotransfected with plasmids expressing RacN17 and Pak-PID were treated with 30 ng/ml human TNF- for 40 min before lysing the cells. Dual luciferase assay was performed, and NFB activity was determined as described in the legend of Fig. 5A . Data represent the mean ± SE from three independent experiments performed in duplicate. *, significant increase in NFB-luciferase activation (p < 0.001).

Finally, it is known that many viruses use the TNF- pathway to activate NFB (55) . To determine the role of TNF- in the KSHV-GPCR-Pak1-NFB signaling axis, we investigated whether TNF- treatment could enhance KSHV-GPCR-dependent NFB activation. Although TNF- could increase NFB activation by KSHV-GPCR only marginally (Fig. 6C) , it could overcome the inhibition of this signaling caused by RacN17 and Pak-PID by about 50–60% (Fig. 6C) . These results suggest that KSHV-GPCR signaling to NFB through Pak1 does not require activation of TNF-, but TNF- can augment KSHV-GPCR regulation of NFB through a separate pathway.

	DISCUSSION

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Prior studies have addressed signaling from the KSHV-GPCR based on control of end points such as increased vascular endothelial growth factor (56) , enhanced cell survival (13) , or increased cytokine secretion (57) . This is the first study to analyze the signaling requirements for KSHV-GPCR-induced cell transformation. In this work, we have delineated a direct signaling pathway from KSHV-GPCR through Rac1, Pak1, and IKK, culminating in transcriptional activation through NFB. Furthermore, we have demonstrated a key role for Pak1 activation of NFB in KSHV-GPCR-mediated cell transformation. Thus, this study extends the known involvement of Pak1 in cell transformation to GPCR oncogenes.

Based on the data amassed in this study, we propose the signaling pathway shown in Fig. 7 . In this pathway, KSHV-GPCR induces the activation of Rac1 and Cdc42, most probably through G_i, which further promotes the activation of Pak1. This activation cascade may also involve PI3K, because G_i has been shown to induce PI3K (58 , 59) , which stimulates Rac1 (60 , 61) . Because both PTX and wortmannin inhibit KSHV-GPCR activation of Pak1 (Fig. 3C) and cell transformation (Fig. 6A) , this pathway could be active in KSHV-GPCR signaling. PI3K also stimulates AKT, which can contribute to Pak1 activation to promote cell proliferation and survival (60) . Of relevance, a number of studies have noted that the HIV protein nef interacts and activates Pak1 to promote c-Jun NH₂-terminal kinase activation and increased viral production (62) . Both Rac1 to Pak1 and PI3K to Pak1 activation pathways are essential for nef-mediated pathogenesis of HIV (63 , 64) . Regulation of Pak1 through HIV-nef is also an attractive possibility, because coinfection of HIV is a frequent occurrence in KS patients. Pak1, once activated, further disseminates this signal either directly through NIK or indirectly to IKK leading to phosphorylation of IB and subsequent activation of NFB. Finally, activation of RhoA as a consequence of G_i activation may augment NFB stimulation. This use of multiple pathways to activate NFB would be analogous to the strategy used by Ras to signal to NFB through the PI3K-Akt-IKK as well as Raf-Mek-IKKß pathways (65) . After activation of NFB, it is also reasonable to suppose initiation of a cytokine/autocrine loop involving TNF-, reinforcing virus maintenance of NFB activation.

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Fig. 7. A model for signaling from KSHV-GPCR to NFB in cell transformation. As shown, central signaling axis involves Gi-Rac1-Pak1-IKKß-IB-NFB. KSHV-GPCR also activates the PI3K-Akt pathway signaling to NFB directly through IKK. Signaling between PI3K-Rac1-Pak1/PI3K-Akt-Pak1 is also possible as an added layer of regulation (elaborated in "Discussion"). Solid lines with solid arrows indicate signaling pathways addressed in this study, and dotted lines with open arrows show other possible routes to this pathway.

Moving downstream, our data indicate that Pak1-induced phosphorylation of IKKs is a critical step in mediating NFB activation (Fig. 5) , although it does not assign IKKs as direct Pak1 substrates. Although NFB activation has been demonstrated through both PI3K-Akt and Pak1 in a variety of studies (37) , the critical targets of Pak1 in this pathway remain elusive. Pak1 has been reported to transduce signals from Ras, Raf, or Rac1 to NFB without activating IKK or IKKß. However, dominant-negative mutants of both IKK and IKKß block the signals from Pak1 to NFB, suggesting that both are necessary for Pak signaling (37) . In studies by Pati et al. (53) , dominant-negative mutants of IKKß and IB completely inhibited NFB activation by KSHV-GPCR in a KS endothelial cell line, whereas a dominant-negative IKK mutant only partially inhibited NFB activation. Our data suggest a mode of regulation of NFB activity by Pak1, wherein upon activation by Pak1 or a related kinase, IKKß phosphorylates IB downstream of Pak1. One possibility, as suggested by Frost et al. (37) , is that Pak1 regulates NIK, the protein kinase upstream of IKK or IKKß (Fig. 7) . Placement of Pak1 at the level of NIK is also consistent with data from several other studies (37 , 71 , 72) . In summary, our study indicates that G_i and possibly other heterotrimeric proteins transduce the signal from KSHV-GPCR to the small G protein Rac1 and its effector Pak1, then through IKKß, IB, and NFB, leading to transformation of NIH3T3 cells. Interestingly, as Pak inhibitors block both Ras and KSHV-GPCR signals to NFB, Pak1 lies downstream of both. This suggests a convergence of multiple signals through Pak.

NFB is activated by a diverse set of GPCRs, including receptors for thrombin, platelet-activating factor, and prostaglandin E₂ (73) besides KSHV-GPCR, although the signaling pathways connecting GPCRs and NFB have not been well-defined in these different systems. Some of the possible pathways put forward include the Ras and the Rho GTPase family pathway. Activation of Ras, and consequently Raf and/or pp90rsk, by the ß subunits of the heterotrimeric G proteins leads to increased NFB activity (29) . Mutationally active forms of three different Rho GTPases (Rac1, Cdc42, and RhoA) activate NFB (74) . The Ras effectors PI3K, Akt, and Pak1 are also potentially involved in NFB activation, but the importance of these proteins has not been clearly established in these other systems. Recent reports have shown that KSHV-GPCR enhancement of cell survival and increased cytokine secretion requires NFB. However, the signaling requirements thus far demonstrated for cell survival and cytokine production are nonequivalent, even though both involve NFB induction. KSHV-GPCR up-regulation of IL-8 production is dependent on activation of the RhoA GTPase (12) , whereas enhancement of cell survival has been studied in the context of the signaling from PI3k to Akt to NFB (13) . Our study has not addressed the possible role of RhoA activity in KSHV-GPCR transformation or NFB activation, but contribution of RhoA to these processes remains a formal possibility (Fig. 7) .

Most viruses activate NFB to stimulate the production of cytokines such as TNF-, which in its turn sets up an autocrine loop to keep high levels of constitutive expression of NFB. The existence of such a loop in KSHV-GPCR-NFB signaling cannot be ruled out. However, our experiments have established that TNF- can induce NFB activation under conditions in which the Pak1 signaling pathway is suppressed, suggesting that TNF- signals, in part, through a Pak-independent pathway (Fig. 6C) . Together with reports of the involvement of RhoA in KSHV-GPCR activation of NFB and the data we present herein, it is attractive to postulate that KSHV uses multiple pathways to activate NFB, ensuring constitutive expression of NFB-dependent antiapoptotic and growth-promoting genes in the host cell.

The results presented here indicate that signals to Pak and NFB contribute to cell transformation by KSHV-GPCR. Both PI3K and MAPK pathways are known to be involved in cell transformation signaling. Consequently, we directly examined whether PI3K or MAPK participated in KSHV-GPCR signaling using specific inhibitors. The PI3K inhibitor wortmannin blocked both NFB activation and cell transformation, whereas PD98059, the MAPK pathway inhibitor, inhibited only cell transformation by KSHV-GPCR but not NFB activation (Fig. 6, A and B) . These data suggest that KSHV-GPCR requires at least two different pathways for cellular transformation, one involving PI3K and/or Pak1-NFB and the other involving MEK-MAPK but not NFB. On the other hand, Ras stimulation of NFB was blocked by both inhibitors (Fig. 6B) , suggesting, as previously observed, that PI3K and MAPK signals are both required for NFB stimulation by Ras.

Activation of Pak1 by the KSHV-GPCR oncogene corroborates growing reports of involvement of Pak1 and its isoforms in anchorage-independent cell growth and morphological changes in the cell during cell transformation (32 , 75) . For example, several studies have demonstrated the active role of Pak1 in the increased cell motility, invasion, and angiogenesis exhibited by breast cancer cells as well as in neurofibromatosis 1-mediated cell transformation (34 , 76 , 77) . Pak1 also induces cytoskeletal rearrangements, c-Jun NH₂-terminal kinase activation, and increased viral production in conjunction with the Nef protein of HIV-1 (62) as described previously. In fact, the Nef protein of HIV also participates in the regulation of NFB activity (78) and cellular transformation (79 , 80) , and Pak1 comes to mind as a common signaling molecule for both HIV-nef and KSHV-GPCR. Epidemiological studies have suggested that KSHV is one of the major determinants in the development of KS (81 , 82) . All stages of KS, from the initial patch lesions to the more advanced plaque and nodular stages, are characterized by common immunological and histopathological findings, including angiogenesis and an increased concentration of proinflammatory cytokines. The late nodular stage is characterized by outgrowth of tumorous oligoclonal spindle cells and true sarcoma formation with invasion of the underlying dermal structure. Based on the ability of Pak1 to affect signaling involved in survival, immune response, cell migration, and angiogenesis (32) , activation of Pak1 has the potential to contribute to all these characteristic KS disorders.

	ACKNOWLEDGMENTS

 
We thank Shrikrishna Dadke, Ya Zhuo, and Guolei Zhou for helpful discussions and comments on the paper.

	FOOTNOTES

 
Grant support: NIH grant GM48241, the American Cancer Society, and the University of Pennsylvania Center for AIDS Research (J. F.); NIH training grant CA 09677 (B. H. F.); NIH grant CA63366 (E. A. G.); and Core grant CA06927 (Fox Chase Cancer Center).

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

Requests for reprints: Jeffrey Field, Department of Pharmacology, University of Pennsylvania, School of Medicine, 3620 Hamilton Walk, Philadelphia, Pennsylvania 19104-6084. Phone: (215) 898-1912; Fax: (215) 573-2236; E-mail: field@pharm.med.upenn.edu.

³ J. Chernoff, unpublished data.

Received 1/ 8/03. Revised 9/30/03. Accepted 10/ 6/03.

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