Death Receptor-Induced Activation of Initiator Caspase 8 Is Antagonized by Serine/Threonine Kinase PAK4

Normal cell growth requires a precisely controlled balance betweencell death and survival. This involves activation of differenttypes of intracellular signaling cascades within the cell. Whilesome types of signaling proteins regulate apoptosis, or programmedcell death, other proteins within the cell can promote survival.The serine/threonine kinase PAK4 can protect cells from apoptosisin response to several different types of stimuli. As is thecase for other members of the p21-activated kinase (PAK) family,one way that PAK4 may promote cell survival is by phosphorylatingand thereby inhibiting the proapoptotic protein Bad. This leadsin turn to the inhibition of effector caspases such as caspase3. Here we show that in response to cytokines which activatedeath domain-containing receptors, such as the tumor necrosisfactor and Fas receptors, PAK4 can inhibit the death signalby a different mechanism. Under these conditions, PAK4 inhibitsapoptosis early in the caspase cascade, antagonizing the activationof initiator caspase 8. This inhibition, which does not requirePAK4's kinase activity, may involve inhibition of caspase 8recruitment to the death domain receptors. This role in regulatinginitiator caspases is an entirely novel role for the PAK proteinsand suggests a new mechanism by which these proteins promotecell survival.

INTRODUCTION

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Introduction

The balance between apoptosis and survival in a cell is controlledby various intracellular signaling pathways. A number of differentstimuli can trigger apoptosis in cells, including ligation ofdeath domain receptors such as the Fas receptor or the tumornecrosis factor alpha (TNF- ${alpha}$ ) receptor (2, 52, 72) or deprivationof nutrients such as growth factors or serum (56). Apoptosisis generally mediated by caspase cascades that lead to cleavageor activation of molecules that are important for cell death(9, 59, 68). Cell survival pathways can be mediated by proteinswhich inhibit the caspase cascades at various stages.

Different types of apoptotic stimuli can trigger cell deathby different mechanisms. Fas ligand and the cytokine TNF- ${alpha}$ , forexample, bind to cell surface receptors and in turn induce theactivation and cleavage of the initiator caspases, such as caspase8 and caspase 10. Once activated, caspase 8 can activate twodifferent apoptotic pathways (27). First, it can directly cleaveand activate effector caspases, such as caspases 3 and 7. Effectorcaspases in turn cleave a number of different target proteinsthat play important roles in mediating the apoptotic response(59, 68). Second, caspase 8 can activate a mitochondrial pathwaywhich is mediated by the caspase 8 substrate Bid (29, 43, 45,76). Once it is cleaved by caspase 8, the truncated Bid translocatesto the mitochondria, where it interacts with members of theBcl2 family to promote cytochrome c release. Release of cytochromec from the mitochondria leads to activation of caspase 9 followedby cleavage and activation of caspase 3, leading to apoptosis(26, 27).

Signaling by cytokine receptors such as the Fas receptor andthe TNF receptor (TNFR) actually starts when the receptors trimerizefollowing binding by the ligand. The trimerized receptors recruita number of proteins through their protein-protein interactionmotifs, and these proteins in turn lead to activation of thecaspase cascades (2, 72). The main docking protein of TNFR1is the TNFR-associated death domain protein (TRADD), which bindsto the TNFR via an interaction between the respective deathdomains (33). TRADD then recruits other death domain-containingproteins, including the Fas-associated protein with death domain(FADD) or receptor-interacting protein (RIP), via its deathdomain (7, 14, 32, 33, 66). Finally, FADD can recruit caspase8 to the complex (7, 50), which in turn is cleaved and activated,triggering the apoptotic response described above. In contrast,RIP, together with its interacting protein TRAF, signals tothe NF- ${kappa}$ B pathway which can lead instead to protection from apoptosis(5, 31-33, 44, 65, 78). The major binding partner for the Fasreceptor is FADD, which also binds to the receptor through itsdeath domain (7, 14). FADD in turn binds directly to caspase8, which is activated by oligomerization and self-cleavage (6,49-51). The signaling network that is formed at the death receptorafter stimulation is referred to as the death-inducing signalingcomplex (DISC) (41).

Throughout development, excess cells are eliminated by the processof apoptosis, while other cells are protected from apoptosisby different mechanisms. A number of cell survival pathwaysexist for protecting cells from apoptosis. For example, NF- ${kappa}$ Bcan protect cells from apoptosis by inducing the expressionof genes involved in cell survival (22). Another example ofa protein that can protect cells from apoptosis is the lipidkinase phosphatidylinositol 3-kinase (PI 3-kinase) (12, 21).PI 3-kinase activity is stimulated by exposure to growth factorsor serum. This leads to activation of the survival protein AKT.AKT phosphorylates a number of substrates, including the proapoptoticprotein Bad, leading to its inactivation (18). Phosphorylationof Bad prevents activation of the mitochondrial pathway andcytochrome c release and thereby protects cells from apoptosis(20). For this reason, many cells are highly sensitive to serumdeprivation and undergo apoptosis when grown under low-serumconditions.

The p21-activated kinase (PAK) serine/threonine kinases area family of protein kinases that may also play a protectiverole against apoptosis. The PAK family members were originallyidentified as molecular targets for the Rho GTPases Rac andCdc42 (1, 4, 8, 10, 47, 48; for reviews, see references 3, 16,and 63). There are six members of the PAK family in mammals,which fall into two categories (group A and group B) based ontheir amino acid sequences and functions (35). The group A PAKsconsist of the closely related PAK1, -2, and -3 (4, 8, 47, 48),whereas the group B PAKs consist of PAK4, -5, and -6 (1, 15,53, 75). All of the PAKs contain a GTPase binding domain, whichbinds to the Rho GTPases, and a serine/threonine kinase domainthat is similar to the kinase domain of yeast STE20. The groupA and B PAKs are only approximately 50% identical to each otherin the GTPase binding domain and kinase domain, and they differcompletely throughout the rest of their amino acid sequences(35).

Although they were first identified as proteins that play animportant role in regulating cytoskeletal organization and cellmorphology, the PAKs have also been shown to have importantroles in regulating the apoptotic response, although their effectsdiffer under different conditions. For example, PAK2 is cleavedduring Fas-induced apoptosis in T cells, most likely by caspase3. This was shown to lead to its activation, leading to morphologicaland membrane changes that occur during apoptosis (42, 58, 73).In other studies, however, PAK2 was shown to protect fibroblastsfrom apoptosis in response to various stimuli, including TNF- ${alpha}$ ,serum starvation, and UV irradiation (36). Likewise, PAK1, whichis not cleaved during apoptosis, was reported to protect cellsfrom apoptosis induced by either serum withdrawal in fibroblastsor interleukin-3 withdrawal in lymphoid cells (62, 67). Thesurvival signal induced by PAK1 is apparently due to directphosphorylation of Bad on both serines 112 and 136 (62, 67).PAK2 may also operate by phosphorylating Bad, as well as byactivating mitogen-activated protein (MAP) kinase pathways (36).

We have found that PAK4 can also protect cells from apoptosisin response to a number of different stimuli (23). As is thecase for PAK1, one way that PAK4 may protect cells from apoptosisis by phosphorylating the proapoptotic protein Bad, althoughunlike PAK1, PAK4 phosphorylates Bad specifically on serine112 (23). Consistent with this, we have found that effectorcaspases such as caspase 3 are inhibited in response to severalstimuli in PAK4-expressing cells (23). Here we have found, however,that in response to some types of stimuli, notably ligationof TNF or Fas receptors, PAK4 inhibits apoptosis by a mechanismthat does not depend on its kinase activity. Under these conditions,we have found that PAK4 inhibits apoptosis by inhibiting theactivity of the initiator caspase 8. PAK4 can thereby blockthe caspase cascade by acting upstream of the mitochondrialpathway and effector caspases, rather than by preventing phosphorylationof Bad and cytochrome c release. This may be mediated in partby inhibition of recruitment of caspase 8 to the death receptors.

MATERIALS AND METHODS

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Materials and Methods

Cell culture and transfections. The HeLa pLPC and PAK4 cell lines (23) were cultured at 37°Cin 5% CO₂ and maintained in Dulbecco's modified Eagle's medium(Life Technologies) containing 10% fetal bovine serum (LifeTechnologies), 4 mM glutamine (Life Technologies), and 50 Uof penicillin per ml and 50 µg of streptomycin per ml(Cellgro), supplemented with 1 µg of puromycin per ml.NIH 3T3 pLPC, PAK4wt (55), and PAK4(K350 M) (PAK4KM) cells weremaintained in Dulbecco's modified Eagle's medium with glutamineand antibiotics, containing 10% bovine calf serum (HyClone)and 2 µg of puromycin per ml. Before the experiments,cells were passaged and plated in medium without puromycin.HeLa cells (2.7 million per 10-cm-diameter plates) were transfectedwith Lipofectamine (Life Technologies) according to the manufacturer'sinstructions. For serum deprivation experiments, cells werewashed twice in medium lacking serum and cultured for 24 h inthe presence of 0.1, 0.5, or 10% (complete medium) serum. Cellswere harvested, fixed, stained with propidium iodide, and analyzedby flow cytometry as described previously (23).

Generation of the PAK4K350 M HeLa and NIH 3T3 cell lines. ${Phi}$ NX and BOSC packaging cell lines were transfected by the calciumphosphate method with a retroviral vector plasmid containinga Myc-tagged PAK4K350M sequence (pLPCmycPAK4KM [pNG81]). Viruseswere collected and used to infect HeLa or NIH 3T3 cells, respectively,and positive cells were selected with puromycin. Expanded colonieswere tested for the expression of the Myc tagged PAK4 proteinby Western blotting with Myc or PAK4 antibodies and by immunofluorescence.

Plasmids. pNG81 (pLPCmycPAK4K350M) was obtained by subcloning the EcoRI-StuIfragment of the PAK4K350M sequence (1) in frame with the Mycepitope tag sequence into the pCDNA3 vector and subsequentlyinserting it as a HindIII-XhoI fragment in the pLPC vector.The chimeric receptor expression plasmid pCD120a/CD95, containingthe extracellular domain of CD120a (p55TNFR) and intracellulardomain of CD95 (Fas), was described previously (24). pCDNA3was used as an empty vector or as buffering DNA for transienttransfections. pEBG was used as a control for transfection efficiencyfor the expression of glutathione S-transferase (GST).

Reagents and antibodies. Recombinant human TNF- ${alpha}$ was purchased from R&D Systems; cycloheximide(CHX) and other reagents were purchased from Sigma unless otherwisestated. Monoclonal caspase 8 antibodies (clone 1C12), rabbitpolyclonal cleaved caspase 3 (D175), and human Bid were fromCell Signaling; goat polyclonal TNFR1 antibodies were from R&Dsystems; monoclonal TNFR1 (H-5) and FLIPs/l (G11) antibodieswere from Santa Cruz; monoclonal TRADD (clone 37), RIP (clone38), and FADD (clone 1) were from BD Transduction Labs; monoclonalpoly(ADP-ribose) polymerase (PARP) (clone 4C10-5) antibodieswere from PharMingen; monoclonal CD95 Fas antibodies (cloneCH-11) were from Immunotech; and monoclonal actin antibodies(clone AC-40) were from Sigma. Monoclonal PAK4 antibodies weredescribed previously (55).

Western blot analysis. Horseradish peroxidase-conjugated secondary antibodies werefrom Sigma. Western blot protein bands were visualized by theECL method (Amersham). Stripping of antibodies from membranesafter the ECL reaction was performed according to the manufacturer'sinstructions. Immobilon-P-polyvinylidene difluoride membraneswere from Millipore.

Analysis of TNFR and Fas signaling. For the analysis of endogenous proteins in whole-cell lysatesafter TNF- ${alpha}$ or Fas stimulation, cells were stimulated and collectedas described previously (23) with 10 ng of TNF- ${alpha}$ per ml or 500ng of Fas antibody per ml, with or without 10 µg of CHXper ml. Lysates were then prepared in M2 buffer supplementedwith protease and phosphatase inhibitors, and equal amountsof proteins were loaded on gels for sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) fractionation and Western blotting.

For the experiments involving coimmunoprecipitation of activatedreceptors, protocols were adapted from those described previously(38, 77). For the analysis of the endogenous TNFR1 signalingcomplex, 20 million cells were stimulated with TNF- ${alpha}$ for theindicated times, rinsed in cold phosphate-buffered saline, andlysed in 1 ml of Triton lysis buffer (TLB) (25 mM Tris [pH 7.6],150 mM NaCl, 1% Triton X-100) supplemented with 10 µgof aprotinin and leupeptin per ml, 1 mM Na₃VO₄, 1 mM EDTA, 30mM NaF, 2 mM Na pyrophosphate, and 1 mM phenylmethylsulfonylfluoride for 1 h on ice. One-fiftieth of the clarified lysateswas saved and loaded as a control. The rest was added to 40µl of protein G-agarose beads precoupled with 15 µgof goat TNFR1 antibodies or goat serum (Gibco) as a preimmunecontrol and rotated overnight at 4°C. Immunoprecipitateswere washed twice with 1 ml of lysis buffer, twice with lysisbuffer containing 0.5 M NaCl, and twice again with lysis buffer.Samples were denatured in sample buffer and analyzed by SDS-PAGEand Western blotting.

For the analysis of the Fas signaling complex, cells were seededin 10-cm-diameter plates and transfected the next day with theindicated amounts of pCD120a/CD95 DNA (24) and pCDNA plasmid,to a total of 15 µg, with Lipofectamine. At 48 h aftertransfection, cells were stimulated with TNF- ${alpha}$ and lysed with600 µl of TLB as described above. Immunoprecipitationwas were performed as described above, using 5 µg of TNFRantibodies, with the following washes: two washes in lysis buffer,two washes in high-salt buffer (TLB with 1 M NaCl), one washin lysis buffer, and two final washes in lysis buffer with thedetergent omitted.

RESULTS

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Results

PAK4 kinase activity is not required for protection from TNF- ${alpha}$ -induced apoptosis. Although PAK4 is widely expressed during development, it isexpressed at quite low levels in many adult cells and tissues(1; J. Qu and A. Minden, unpublished results). We have thereforebeen able to generate stable cell lines which express PAK4 atlevels that are higher than those of endogenous PAK4 (Fig. 1).These cell lines provide a good model system for studying thefunction of PAK4 in apoptosis and survival. We have previouslyshown that overexpression of PAK4 in different cell lines providesa survival advantage over control cells following applicationof death-inducing stimuli, protecting cells from undergoingapoptosis. To determine whether PAK4's ability to protect cellsfrom apoptosis depends on its kinase activity, stable cell linescontaining empty vector, wild-type PAK4, or kinase-dead PAK4[PAK4(K350M)/PAK4KM] were treated with death-inducing stimuli.As expected, after TNF- ${alpha}$ treatment of HeLa cells or serum deprivationof NIH 3T3 cells, the expression of wild-type PAK4 inhibitedapoptosis under both conditions (23) (Fig. 1). Surprisingly,however, although PAK4(K350M) did not protect cells from serumdeprivation-induced apoptosis, it was as efficient as wild-typePAK4 in inhibiting TNF- ${alpha}$ -induced apoptosis (Fig. 1). This suggeststhat at least in response to TNF- ${alpha}$ stimulation, PAK4 may protectHeLa cells from undergoing apoptosis by a mechanism that doesnot directly involve its ability to phosphorylate substratessuch as Bad.

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FIG. 1. PAK4 kinase activity is not necessary for protection against death stimuli in HeLa cells. Stably transfected PAK4 protein was overexpressed in HeLa and NIH 3T3 cell lines (A) pLPC or PAK4 (PAK4 refers to wild-type PAK4 in all of the figures) HeLa cell extracts were probed with PAK4 antibodies to detect endogenous (PAK4) or stably transfected (hemagglutinin [HA]-PAK4) levels. (B) Expression of HA-tagged wild-type PAK4 (HA-PAK4), Myc-tagged wild type PAK4, Myc-tagged PAK4KM (kinase dead) in HeLa or NIH 3T3 cell lines was detected as described above. (C) Kinase-dead PAK4 cell lines are protected from TNF- ${alpha}$ induced apoptosis. HeLa control cells (pLPC) or HeLa cells expressing wild-type (PAK4) or kinase-dead (PAK4KM) PAK4 were left unstimulated (un) or stimulated with 10 ng of TNF- ${alpha}$ per ml and 10 µg of CHX per ml for the indicated time in hours (TNF/CHX). Cells were collected, fixed, and stained with propidium iodide, and DNA content was analyzed by flow cytometry. The percentage of cells displaying DNA content lower than the G₁ peak (sub-G1%) is shown in the graph. (D) PAK4 kinase activity is required for protection from serum deprivation-induced apoptosis in NIH 3T3 cell lines. NIH 3T3 control cells (pLPC) or cells expressing wild type (PAK4) or kinase-dead (PAK4KM) PAK4 were cultured for 24 h in medium containing 10% (complete), 0.5%, or 0.1% serum. Cells were collected, and apoptosis (sub-G1%) was analyzed by flow cytometry as described above. Data for one representative experiment of at least three independent ones are shown. (NIH 3T3 cells were used in these experiments because HeLa cells were resistant to serum deprivation-induced apoptosis.)

TNF- ${alpha}$ -induced activation of initiator caspase 8 and effector caspase 3 is inhibited in PAK4-expressing cell lines. Since PAK4 protects cells from TNF-induced apoptosis independentlyof its kinase activity, and therefore presumably independentlyof Bad phosphorylation, we were interested in determining whatsteps of the TNF-induced death pathway were blocked by PAK4.One possibility is that PAK4 can affect initiator caspases andthereby function upstream of, or independently of, the mitochondrialpathway itself. To test this, cleavage of the initiator caspase8 and the effector caspase 3 was observed following TNF- ${alpha}$ treatmentof the different stable HeLa cell lines. Normally, engagingTNFR1 (also called p55 TNFR or CD120a) with TNF- ${alpha}$ in the presenceof CHX causes initiator pro-caspase 8 (a and b forms [p57/55])to be processed and cleaved into intermediate and active fragments(p43/41, p20, p18, and p10). Active caspase 8 in turn can eitheractivate the mitochondrial pathway or cleave effector caspasessuch as caspase 3. As expected, after 2 h of stimulation, considerableamounts of intermediate and active caspase 8 fragments (p43/41and p18) could be detected in the control cells. By 4 h mostof the proenzyme had undergone processing, as detectable bythe decreased amount of full-length protein (Fig. 2). Effectorcaspase 3 activation followed a similar time course, as judgedby the appearance of the active p17 fragment. In contrast, incells overexpressing PAK4, cleavage of both caspase 8 and caspase3 was dramatically reduced and delayed (Fig. 2). As previouslyobserved (23), the terminal apoptotic process is actually delayedrather than completely blocked in PAK4 cells, since caspaseactivation (see also Fig. 4) and DNA fragmentation (not shown)eventually occur at the latest time points but remain substantiallylower than in control cells, indicating that the onset of theapoptotic program is delayed. Thus, following TNF- ${alpha}$ stimulation,not only was effector caspase 3 activation inhibited, but initiatorcaspase 8 was also affected. This did not appear to be due tochanges in the levels of cellular Fas-associated death domain-likeinterleukin-1-converting-enzyme-like inhibitory protein (cFLIP),which has been shown to have a role in inhibiting caspase 8activation in T cells (34, 40, 61) (Fig. 2). These results suggestthat the role of PAK4 in inhibiting apoptosis by TNF- ${alpha}$ residesat the level of initiator caspases.

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FIG. 2. Activation of both effector and initiator caspase is affected in PAK4 cell lines. HeLa control (pLPC) or PAK4 cells were left untreated (-) or stimulated with 10 ng of TNF- ${alpha}$ per ml and 10 µg of CHX per ml (+), with TNF- ${alpha}$ alone (T), or with CHX alone (C) for the indicated times in hours. Cells were harvested, and equal amounts of protein lysates were separated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with antibodies against caspase 8 (A and B), cleaved caspase 3 (C), or cFLIP (D). PAK4 expression levels and equal loading of the samples were detected by probing the extracts with hemagglutinin (HA) (E) and actin (F) antibodies. Specific bands of caspase 8 a and b proenzymes (proCaspase 8) and proteolytic products (p43/41), active p18 fragment, caspase 3 active p17 fragment, cFLIPshort, HA-PAK4, and actin are indicated by arrows.

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FIG. 4. Cleavage of initiator caspase substrate Bid is affected in wild-type and kinase-dead PAK4 cell lines. HeLa control cells (pLPC) or cells expressing wild-type PAK4 (PAK4) or two independent kinase-dead cell lines (PAK4KMcl3 and PAK4KMclE2) were left unstimulated (-) or stimulated with 10 ng of TNF- ${alpha}$ per ml and 10 µg of CHX per ml for the indicated times in hours (hs TNF/CHX). Cells were harvested, and equal amounts of protein lysates were separated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with antibodies against caspase 8 (A and B), cleaved caspase 3 (B), or Bid (D). PAK4 expression levels and equal loading of the samples were detected by probing the extracts with Myc (E), hemagglutinin (HA) (F), and actin (G) antibodies. Specific bands of caspase 8 a and b proenzymes (proCaspase 8) and proteolytic products (p43/41), active p18 fragment, caspase 3 active p17 fragment, or Bid full-length protein or p15 active fragment (cleaved Bid), wild-type HA-PAK4 or kinase-dead myc-PAK4, and actin are indicated by arrows. An unspecific reactive band (us) migrating near the p15 Bid fragment is indicated by an asterisk.

PAK4-expressing cells are resistant to anti-FAS-induced apoptosis. To determine whether PAK4 affects other death receptor cascadesin addition to the TNF- ${alpha}$ cascade, stable HeLa cell lines weretreated with anti-Fas receptor antibodies. Apoptosis was thendetected by observing cleavage of the effector caspase substratePARP (Fig. 3). In control cells, effector caspase activation(as judged by the appearance of the p85 PARP cleavage product)was detected as early as 2 h after anti-FAS stimulation in thepresence of CHX, when more than 50% of the PARP protein hadbeen cleaved, as most of the cells had started the apoptoticprogram. By 4 h the full-length p116 PARP protein was detectableonly at very low levels, as most of the protein had been cleaved.Conversely, when PAK4 cells were treated with the same stimuli,caspase activation was significantly delayed. After 2 h onlya small portion of PARP had been cleaved in the PAK4 cells,and at 4 h the full-length p116 was still detectable. (Fig.3). A similar delay in the activation of caspases was observedin kinase-dead PAK4 cells. Importantly, as in the TNF- ${alpha}$ -treatedcells, caspase 8 cleavage was also significantly impaired inthe PAK4-containing Fas-treated cells (Fig. 3). Thus, as withTNF- ${alpha}$ -treated cells, Fas-induced apoptosis and caspase 8 activationwere reduced in the presence of both wild-type and kinase-deadPAK4.

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FIG. 3. Stable cell lines expressing PAK4 are resistant to anti-FAS-induced apoptosis. HeLa control (pLPC) and wild-type (PAK4) or kinase-dead (PAK4KM) PAK4 cells were left unstimulated (ns) or treated with 500 ng of anti-Fas per ml and 10 µg of CHX per ml (F + C), for the indicated time in hours. Cells were harvested, and equal amounts of protein lysates were separated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with antibodies against PARP (A), caspase 8 (B), or Bid (C). PAK4 expression levels and equal loading of the samples were detected by probing the extracts with hemagglutinin (HA) and Myc antibodies (D) and actin antibodies (E). (Wild-type PAK4 is HA tagged, and PAK4KM is Myc tagged). Specific bands of PARP full-length p116 protein or cleaved p85 product, caspase 8 a and b proenzymes (proCaspase 8) and proteolytic products (p43/41), active p18 fragment, active Bid p15 fragment (cleaved Bid), wild type HA-PAK4 or kinase dead myc-PAK4 (PAK4), and actin are indicated by arrows. An unspecific reactive band (us) migrating near to the p15 Bid fragment is indicated by an asterisk.

Suppression of Bid cleavage parallels caspase 8 inhibition in PAK4-expressing cells. Although caspase 8 activation is necessary for death receptor-inducedapoptosis (39, 71), in many cell types (also described as typeII cells) the mitochondrial pathway is also required in orderto induce full activation of effector caspases and cell death(60). Cleavage and activation of the proapoptotic Bcl2 familymember Bid (by initiator caspase 8) was shown to be necessaryfor the activation of the mitochondrial pathway by death receptors(29, 43, 45, 76). In order to rule out the possibility thatthe small amount of caspase 8 activity still present in PAK4cells was still sufficient to cause normal activation of thispathway, the caspase 8 substrate Bid was analyzed. When TNF- ${alpha}$ -treatedcontrol cell lysates were analyzed (Fig. 4D), the full-lengthBid protein decreased over time, and the cleavage product p15was detectable as early as 2 h, coincident with the appearanceof the active caspase 8 fragment p18 (as well as the caspase3 fragment p17). In contrast, when PAK4-expressing cells wereanalyzed, the level of full-length Bid remained high at theanalyzed time points. Only a small amount of p15 was detectableat the latest time point, and this coincided with a slight increasein the caspase 8 p18 fragment and the caspase 3 p17 fragment(Fig. 4). Similar results were obtained when anti-FAS-treatedcells were analyzed (Fig. 3C). Most importantly, they indicatethat the low level of caspase 8 seen in response to TNF- ${alpha}$ wasnot sufficient to cause normal activation of the mitochondrialpathway. These results lend further support to the hypothesisthat signaling by the death receptors TNFR1 and Fas is mostlikely compromised at the level of caspase 8 activation in PAK4-expressingcell lines.

TNF- ${alpha}$ -induced association of TRADD and RIP with the TNFR1 receptor is not inhibited by PAK4 expression. Upon binding with their ligands, receptors of the TNF ligandfamily trimerize and recruit a number of proteins through theirprotein-protein interaction motifs (2, 72), as described inthe introduction (Fig. 5, diagram). Given the defects in initiatorcaspase activation in PAK4-expressing cells, we were interestedin determining whether there were defects in the recruitmentof TNFR1-interacting proteins in the presence of PAK4. Cellscontaining empty vector, wild-type PAK4, or kinase-dead PAK4were stimulated with TNF- ${alpha}$ , and lysates were collected at differenttime points. After immunopurification of the TNFR1, precipitateswere analyzed by Western blotting for the presence of the differentinteracting proteins (Fig. 5). After 5 min of stimulation, TNF- ${alpha}$ -dependentbinding of TRADD and RIP to the p55 receptor could be detected.This interaction decreased at a later time points (15 and 30min). (Under these conditions, it was not possible to detectthe association of FADD [Fig. 5D] or caspase 8 [not shown]).While in wild-type PAK4 cells a lower recruitment of RIP wasobserved, this defect was not detected in PAK4KM cells. Ourresults indicate that expression of PAK4 had no major effecton recruitment of TRADD and RIP to the TNFR.

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FIG. 5. TNF- ${alpha}$ -induced association of TRADD with the TNFR1 receptor is not inhibited by PAK4 expression. HeLa control (pLPC) or wild-type (PAK4WT) or kinase dead (PAK4KM) PAK4 cells were left untreated (un) or stimulated with 10 ng of TNF- ${alpha}$ per ml for the indicated times in minutes (min TNF- ${alpha}$ .). Cells were harvested, and equal volumes of protein lysates (WCL) were analyzed by Western blotting as described below or used for immunopurification (Ip) (1/100 of total extracts) with goat antibodies against the extracellular domain of p55 TNFR (TNFR1) or preimmune goat serum (goat immunoglobulin G [IgG]). Immunopurified complexes and whole-cell lysates were fractionated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with mouse antibodies against RIP (A and a), TNFR1 (B), TRADD (C and c), or FADD (D and d). Specific bands are indicated by arrows on the right. Migration positions of IgG heavy (IgG H) and light (IgG L) chains are also indicated. A diagram of TNFR-interacting proteins is also shown.

Caspase 8 binding to the Fas DISC is partially blocked in PAK4-expressing cells. Recruitment of FADD and caspase 8 to the endogenous TNFR1 couldnot be detected in the experiment described above. In fact,in previous work, caspase 8 binding to TNFR1 could be detectedonly when the proteins were overexpressed (6). Therefore, inorder to analyze the recruitment of FADD and caspase 8 to deathdomain receptors, we evaluated their binding after activationof a transfected Fas receptor. To visualize the Fas receptorDISC, cells were transfected with a receptor that contains theextracellular domain of CD120a (p55 TNFR1) and the intracellulardomain of CD95 (Fas/Apo-1) (24) (Fig. 6A). Control cells consistentlyexpressed only low levels of the transfected receptor, evenwhen large amounts of DNA were transfected. This was probablydue to the fact that apoptosis occurred when high levels ofreceptor were expressed (24). In contrast, when PAK4 cells weretransfected with the same amounts of receptor DNA, high expressionlevels were obtained (Fig. 6A), even though both cell typeshad equivalent transfection efficiencies (see expression ofGST, bottom panel of Fig. 6A). Therefore, in order to compareDISC formation in the two cell lines, the amount of receptorexpression plasmid DNA was titrated in order to obtain similarlevels of the transfected receptor in both cell types. Cellswere then stimulated, and binding of the DISC proteins was observedfollowing receptor immunoprecipitation (Fig. 6B). The amountof FADD that was recruited to the receptor appeared to be thesame for both control and PAK4 cells (Fig. 6B). However, theoverall recruitment of caspase 8 was diminished in PAK4-expressingcells, as illustrated by densitometry quantitation of the caspase8 and receptor bands of the immunoprecipitates (Fig. 6C). Processingof the small amount of caspase 8 protein that was present inthe complex was not inhibited, since the partially cleaved precursorswere detectable (Fig. 6B). Similar results were obtained withPAK4KM cells, where high levels of transfected receptor andlower caspase 8 recruitment were observed (not shown). Thesedata indicate that pro-caspase 8 recruitment at the Fas DISCis reduced in the presence of excess PAK4.

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FIG. 6. PAK4-expressing cells show decreased Fas DISC formation. (A) The transfected TNFR/Fas chimeric receptor in highly expressed in PAK4 cell lines. HeLa control (pLPC) or wild-type PAK4 cells were transfected with empty vector (-) or the indicated amounts (in micrograms) of TNFR/Fas chimeric receptor (pCD120a/CD95) or GST (pEBG) expression vector. After 48 h, cells were harvested and equal volumes of protein lysates (1/100 of total extracts) (WCL) were analyzed by Western blotting as described below or used for immunopurification (Ip) with goat antibodies against the extracellular domain of p55 TNFR ( ${alpha}$ TNFR1) or preimmune goat serum (GS). Immunopurified complexes and whole-cell lysates were fractionated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with mouse antibodies against TNFR1 or GST. Specific bands are indicated by arrows on the right. Migration positions of the TNFR/Fas chimera are indicated by a brace. (B) Recruitment of caspase 8 is compromised in stable PAK4 cell lines. HeLa control (pLPC) or wild-type PAK4 cells were transfected with the indicated amounts (in micrograms) of TNFR/Fas chimeric receptor (DNA pCD120a/CD95) expression vector. After 48 h, cells were left untreated (-) or stimulated with 10 ng of TNF- ${alpha}$ per ml for the indicated time in minutes and harvested. Equal volumes of protein lysates were analyzed by Western blotting as described below or used for immunopurification (1/100 of total extracts) with goat antibodies against the extracellular domain of p55 TNFR or preimmune goat serum. Immunopurified complexes were fractionated by SDS-PAGE, transferred to polyvinylidene difluoride membranes, and probed with mouse antibodies against caspase 8 or FADD. The blot probed with caspase 8 antibodies was stripped and reprobed with mouse antibodies against TNFR1 to verify TNFR1 and TNFR/Fas expression levels (as indicated at the left of the middle panel). Specific bands are indicated by arrows on the right. Migration positions of the TNFR/Fas chimera are indicated by a brace. Migration positions of IgG heavy and light chains are also indicated. To verify equal loading, the lysates (WCL) were analyzed by Western blotting for PAK4 (HA-PAK4), full-length caspase 8 (proCaspase8), FADD, and actin, as indicated. A diagram of the proteins interacting with the Fas intracellular domain of the TNFR/Fas chimeric receptor is also shown. (C) Quantitation of the caspase 8 signal in the DISC shows reduced caspase 8 protein per amount of receptor in PAK4 cells. The pro-caspase 8 bands of the top panel of panel B and the TNFR1 and TNFR/Fas bands (receptor) of the middle panel of panel B (pLPC and PAK4 lanes) were quantitated by densitometry (NIH Image). The densities of pixels in equal areas were measured, and backgrounds (measured in the GS Ip lanes) were subtracted. Receptor amounts for the single Ips were expressed as values relative to the amount of receptor present in the pLPC (ns) Ip lane. The relative amount of caspase 8 pixels shown in the graph was obtained by dividing the measured value of caspase 8 by its relative receptor levels (relative density of pixels). (The lowest relative value obtained [PAK4 ns lane] was similar to background levels and was set as the zero point of the y axis.)

DISCUSSION

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Discussion

Since inhibition of apoptosis can lead to pathologies such ascancer (28), it is extremely important to understand the molecularmechanism by which cells protect themselves from apoptosis.Our previous studies indicate that PAK4 overexpression protectscells from several different kinds of apoptotic stimuli (23).While other PAKs can also promote cell survival, PAK4 appearsto be most directly involved in the oncogenic process. Unlikeother PAKs, for example, PAK4 is highly transforming in fibroblasts(55). Furthermore, while it is expressed at low levels in mostadult tissues, PAK4 is overexpressed in a wide array of tumorcell lines (11). Our results raise the possibility that therole of PAK4 in transformation may be mediated at least in partby PAK4's antiapoptotic role. It is therefore of great interestto understand the mechanism by which PAK4 exerts its survivaleffects in cells.

One way that PAK4 may protect cells from apoptosis is by phosphorylatingthe proapoptotic protein Bad (23), and other PAK family membersmay operate by a similar mechanism (36, 62, 67, 74). However,we found that although in NIH 3T3 fibroblasts PAK4 kinase activityis required for, and correlates with, the cell survival responsefollowing serum deprivation (23), it is not required for protectionfrom death receptor-induced apoptosis in epithelial cells. Thisindicates that in response to death receptor signals, PAK4 canoperate by a mechanism that does not depend on its kinase activity.This effect was also evident in transient-transfection experiments,where both wild-type and kinase-dead PAK4 expression plasmidsconferred lower sensitivity to TNF-induced apoptosis (not shown).

Although we previously showed that effector caspases are inhibitedin PAK4-expressing cells (23), here we have found that in responseto death receptors, the initiator caspase 8 is also inhibitedwhen PAK4 is overexpressed. Cleavage of the caspase 8 substrateBid is also inhibited in PAK4-expressing cells, which furthersupports the idea that PAK4 functions at the level of caspase8. In HeLa cells after TNF/CHX treatment, caspase 8 and Bidcleavage has also been shown to occur (with time courses similarto the ones we observed) under conditions where the mitochondrialpathway is inhibited and caspase 3 activation is not observed(54). In this perspective, Bid cleavage thus occurs becauseit is a target for caspase 8, and its cleavage cannot be explainedby a possible feedback loop. Taken together, these results suggestthat PAK4 can block apoptosis early in the caspase cascade.

We do not yet know how PAK4 inhibits caspase 8 activity. However,we have ruled out the possibility that PAK4 functions by causingchanges in the protein levels of FLIP, which can affect theactivity of caspase 8 (13, 34, 40). Receptor activation alsoappeared to occur normally in the presence of overexpressedPAK4. This was evident by a normal interaction between TNFR1and its binding protein TRADD in the PAK4-expressing cells,as well as between the Fas receptor and FADD. However, recruitmentof caspase 8 (which binds via FADD) to the Fas receptor wassuppressed in the PAK4-expressing cells. Processing to the intermediate(inactive) fragments seemed to occur normally, but it has beenshown that partial processing is not sufficient to induce apoptosis(40, 70). These data, together with the inefficient formationof the active p18 fragment observed in cell lysates, indicatethat the low recruitment of caspase 8 that we observe in PAK4cells is not sufficient to induce full activation. We were notable to detect caspase 8 recruitment to the activated endogenousTNFR1 receptor in any of the cell lines. This is most likelydue to the fact that this interaction, although well established,is observed only when the proteins are ectopically overexpressed(6). We expect that caspase 8 recruitment to the TNFR1 is alsoinhibited by PAK4, however, since this recruitment is also mediatedby FADD. Furthermore, caspase 8 cleavage was similarly inhibitedin both TNFR1- and Fas-stimulated cells.

The regulation of caspase 8 activity and recruitment is a totallynew function for PAK4, and our results suggest a novel mechanismfor PAK4 inhibition of apoptosis. Recently, caspase 8 has alsobeen implicated as a target for several other cell survivalproteins. For example, AKT, a survival protein and target ofthe PI 3-kinase pathway, was previously been shown to inhibitapoptosis by phosphorylating Bad as well as by activating theNF- ${kappa}$ B pathway (19, 46, 57, 67). Recently, however, activatedAKT has also been shown to inhibit caspase 8 activation, aswell as its recruitment to the Fas DISC, and this is thoughtto contribute to its role in protecting T cells from Fas-inducedapoptosis (37). PI 3-kinase, which can activate AKT, was alsorecently shown to protect cells from apoptosis by inhibitingcaspase 8 activity. However, unlike in the previous study, caspase8 recruitment to the DISC was found to be unaffected by PI 3-kinase.Instead, its processing seems to be impaired via a mechanismthat controls lateral diffusion and aggregation of CD95 (69,70). Other signaling proteins that have recently been shownto protect cells from Fas-induced apoptosis via inhibition ofcaspase 8 include protein kinase C and MAP kinase (25, 30).In the case of protein kinase C, recruitment of both FADD andcaspase 8 to the receptor was inhibited, while DISC assemblywas unaffected in response to MAP kinase. Thus, while Bad phosphorylationand the mitochondrial pathway have been considered to be primarytargets for several cell survival pathways, caspase 8 is emergingas a new target for several important apoptosis inhibitors.

Our results indicate that PAK4 is one of the growing numberof cell survival proteins recently shown to inhibit apoptosisat the level of caspase 8 activity. It will be interesting todetermine the molecular mechanism by which PAK4 inhibits caspase8 activity and, possibly, recruitment to the DISC. One possibilityis that it operates by activating one of the pathways describedabove. However, incubation with either MAP kinase inhibitorsor PI 3-kinase inhibitors did not affect PAK4's ability to inhibitcaspase 8 activity and apoptosis (data not shown). Since a kinase-inactiveform of PAK4 can inhibit caspase 8 activity as efficiently aswild-type PAK4 (Fig. 4), our results indicate that PAK4 canoperate a mechanism that does not depend on its kinase activity.Interestingly, other members of the PAK family have been shownto regulate some cellular functions, such as cytoskeletal organization,independently of their kinase activity (17, 64). It has beensuggested, therefore, that PAKs operate not only as proteinkinases but also as scaffold proteins that mediate importantprotein-protein interactions (3, 17). This raises the possibilitythat PAK4 may bind to caspase 8 or other components of the DISCand thereby directly inhibit recruitment of caspase 8 to thereceptor. Another possibility is that PAK4 could control therecruitment of caspase 8 inhibitors or could inhibit the dissociationof silencers of death domains.

In summary, we have found that PAK4 inhibits death domain-inducedapoptosis by inhibiting the initiator caspase 8. Similarly,recruitment of caspase 8 to death domain receptors is also partiallyinhibited in PAK4-expressing cells. This is a novel functionfor PAK4, and our results indicate that in addition to phosphorylating,on serine 112, the proapoptotic protein Bad (23), PAK4 can alsofunction by inhibiting the activities of initiator caspases.

ACKNOWLEDGMENTS

This work was supported by a grant from the NIH (CA76342) andby an American Scientist Development grant from the AmericanHeart Association to A.M.

FOOTNOTES

* Corresponding author. Mailing address: Columbia University, Biological Sciences MC 2460, Sherman Fairchild Center, Room 813, 1212 Amsterdam Ave., New York, NY 10027. Phone: (212) 854-5632. Fax: (212) 854-1559. E-mail: agm24{at}columbia.edu.

Present address: Università degli Studi di Milano, Dipartimentodi Scienze Biomolecolari e Biotecnologie, Milan, Italy.

REFERENCES

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