Regulation of Protein Kinase C Inactivation by Fas-associated Protein with Death Domain*

Background: PKC is extremely important for a wide array of cellular processes. However, its inactivation is poorly understood. Results: FADD deficiency or phosphoryl-mimicking mutation (FADD-D) leads to accumulation of phosphorylated PKC and sustained signaling. Conclusion: The apoptotic adapter FADD is required for PKC dephosphorylation, degradation and signaling inactivation and may be regulated by its phosphorylation. Significance: FADD is critical for PKC dephosphorylation, stability, and signaling termination. Protein kinase C (PKC) plays important roles in diverse cellular processes. PKC has been implicated in regulating Fas-associated protein with death domain (FADD), an important adaptor protein involved in regulating death receptor-mediated apoptosis. FADD also plays an important role in non-apoptosis processes. The functional interaction of PKC and FADD in non-apoptotic processes has not been examined. In this study, we show that FADD is involved in maintaining the phosphorylation of the turn motif and hydrophobic motif in the activated conventional PKC (cPKC). A phosphoryl-mimicking mutation (S191D) in FADD (FADD-D) abolished the function of FADD in the facilitation of the turn motif and hydrophobic motif dephosphorylation of cPKC, suggesting that phosphorylation of Ser-191 negatively regulates FADD. We show that FADD interacts with PP2A, which is a major phosphatase involved in dephosphorylation of activated cPKC and FADD deficiency abolished PP2A mediated dephosphorylation of cPKC. We show that FADD deficiency leads to increased stability and activity of cPKC, which, in turn, promotes cytoskeleton reorganization, cell motility, and chemotaxis. Collectively, these results reveal a novel function of FADD in a non-apoptotic process by modulating cPKC dephosphorylation, stability, and signaling termination.

PKC has been shown to modulate the recruitment of FADD to Fas (19 -21). Specifically, PKC has been shown to promote FADD phosphorylation, which, in turn, has been proposed to be an important mechanism for Fas resistance (22). Phosphorylation of serine 191  in the C terminus of FADD has been proposed to be critical for its non-apoptotic function. Mice bearing the mutation mimicking constitutive phosphorylation (S191D) of FADD are immunologically compromised, similar to FADD-deficient mice (23). FADD is highly phosphorylated in tumors with poor prognosis (24 -26). Potential regulators of non-apoptotic activities of FADD, including CKI␣, a kinase that mediates FADD phosphorylation, have been implicated in regulating non-apoptotic activities of FADD (27,28). However, the functional consequence of FADD phosphorylation at cellular levels has yet to be elucidated.
The activation mechanisms of PKC are well documented, but the molecular mechanisms of PKC inactivation are less well understood. Dephosphorylation of TM and HM are critical for the inactivation and degradation of PKC ␣ and ␤II (29 -31). Several phosphatases are linked to TM and HM dephosphorylation. The heterotrimeric type 2A phosphatase (PP2A) physically associates with PKC and dephosphorylates PKC␣ and ␤ upon phorbol 12-myristate 13-acetate (PMA) stimulation on the membrane (32,33). Both PP2A and PP1 can dephosphorylate PKC␣ and ␤II in vitro (34,35). A recent report showed that PH domain and Leucine rich repeat Protein Phosphatases (PHLPP), a novel Ser/Thr phosphatase, can destabilize cellular PKC␣ and ␤II by dephosphorylating the HM of PKC (36).
Here, we report that FADD is required for the PP2A catalytic subunit to recruit cPKC. In the absence of FADD, endogenous PKC␣ no longer interacted with PP2Ac, so was not dephosphorylated and resistant to degradation. More interestingly, the S191D mutation abolished the ability of FADD to promote PP2Ac recruiting PKC␤II and promoted the resistance of PKC␣ and PKC␤II to degradation. Both FADD deficiency and the S191D mutant enhanced cPKC phosphorylation, stability, and signaling. Moreover, up-regulated cPKC signaling promoted cytoskeleton remodeling and cell motility. Collectively, these findings suggest that FADD could regulate cPKC dephosphorylation and signaling termination.
Cell Culture, Stable Cell Line Construction via Retrovirus Infection, and Mice-293T and MEFs were cultured in DMEM (Hyclone) containing 10% FBS (Hyclone) with 50 units/ml penicillin/streptomycin. FADD mutant cell lines, FADD-A and FADD-D, were constructed on the basis of FADD Ϫ/Ϫ MEFs. The construction and validation of all cell lines were performed in the laboratory of Dr. Astar Winoto (University of California, Berkeley). Briefly, FADD-A and FADD-D mutant cDNAs were generated using PCR, as described previously (23), subcloned into the retroviral vector MSCV-Zeocin, and transfected into Bosc packing cells. Supernatant was used to infect FADD KO MEFs. Infected MEFs were selected with Zeocin for 1 month. The expression level of FADD and FADD mutants was examined using Western blot analyses and was similar across different MEFs. The FADD phosphorylation mutant mice (FADD-D in FADD Ϫ/Ϫ alleles) were generated as reported previously (23). Briefly, the FADD-D transgenic mice were generated and then mated to FADD ϩ/Ϫ mice for at least two generations to obtain mice that express only FADD-D (with FADD Ϫ/Ϫ alleles). The mice were housed in an Association for Assessment and Accreditation of Laboratory Animal Care Jiangsu Province-accredited specific pathogen free (SPF) animal facility in Nanjing Drum Tower Hospital, and all animal protocols were approved by the Animal Care and Use Committee of the School of Life Sciences of Nanjing University.
Immunoprecipitation-Muscular tissues were homogenized in a lysis buffer containing 50 mM Tris-HCl (pH 7.4), 250 mM NaCl, 0.5%Triton X-100, 50 mM NaF, 2 mM EDTA, 1 mM Na 3 VO 4 , and protein inhibitor mixture and immunoprecipitated with anti-PKC␤II antibody and protein G-agarose (Millipore). MEFs were directly lysed in the lysis buffer. The immunoprecipitates were washed six times with lysis buffer and subjected to Western blot analysis.
Phosphatase Activity Assay-Cells were lysed in lysis buffer without NaF and Na 3 VO 4 and centrifuged for 20 min at 13,000 ϫ g. PP2Ac was immunoprecipitated, and the activity was measured with the PP2A immunoprecipitation phosphatase assay kit (Millipore).
F-actin Staining, Wound Closure, Transwell Assays, and Chemotaxis-After the indicated treatments, cells were fixed with 4% formaldehyde for 1 h, penetrated with 0.5% Triton X-100 for 1 h, and then stained with Texas Red-X phalloidin for 1 h. F-actin was then visualized by microscopy (Carl Zeiss, Axioplan 2). For the wound closure assay, confluent cell monolayers were cultured in serum-free DMEM for 24 h and scraped manually with a pipette tip. The culture medium was replaced with fresh medium containing PMA or FBS. The transwell migration assay was performed using an 8-m PET 24-well Millicell culture insert with hanging geometry (Millipore). Cells were cultured in serum-free medium overnight and treated with inhibitor for 2 h before trypsinization. 100-l single-cell suspension at the concentration of 10 6 cells/ml was added to the inner side of the transwell. After 5 h, cells on the inner side of the membrane were wiped clean with a cotton swab. Cells on the outer side were fixed with 4% formaldehyde prior to staining with crystal violet. Images were captured with a ϫ10 objective lens. The average number of migrated cells in five to six randomly chosen fields of view per insert was taken to quantify the extent of migration. For the chemotaxis assay, splenocytes or mesenteric lymphocytes were isolated and cultured in serum-free medium for 2 h. A single-cell suspension was used for the transwell assay. After stimulation with SDF-1 or FBS, migrated cells were quantified using a QCM TM Chemotaxis cell migration assay (Millipore).

RESULTS
FADD Regulates cPKC Protein Levels-To study the effects of FADD on PKC, we examined FADD-deficient murine embryonic fibroblast cells (FADD Ϫ/Ϫ MEFs). Interestingly, we found that protein levels of all cPKCs and one nPKC, PKC␦, were increased in FADD Ϫ/Ϫ MEFs as compared with FADD ϩ/ϩ MEFs (Fig. 1A). In contrast, the protein levels of other nPKCs, such as PKC⑀, and atypical PKCs, such as PKC, in FADD Ϫ/Ϫ MEFs were similar to levels in FADD ϩ/ϩ MEFs (Fig. 1A). To examine whether the accumulation of cPKC and nPKC in FADD Ϫ/Ϫ MEFs might be attributable to increased stability, we treated cells with PMA in a long-term manner (12 h) with lower and milder concentrations that induced endogenous PKCs degradation. Compared with that of FADD ϩ/ϩ MEFs, PKC␣ degradation was greatly reduced in FADD Ϫ/Ϫ MEFs upon PMA treatment (Fig. 1B). Likewise, the degradation of both PKC␤II and PKC␥ was also decreased in FADD Ϫ/Ϫ MEFs ( Fig. 1B and data not shown). In contrast to cPKC, the degradation of PKC␦ was reduced only at low PMA concentrations (Fig. 1B). On the other hand, the rate of degradation of the nPKC PKC⑀ was comparable between FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs (Fig. 1B). Interestingly, we found that the protein levels of FADD are induced in response to PMA treatment in a dose-dependent manner (Fig. 1B).
Because cPKCs such as PKC␣ and PKC␤ are most affected by FADD deficiency, we concentrated our subsequent analysis of PKC␣ and PKC␤. We found that levels of both PKC␣ and PKC␤ mRNA were comparable between FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs after PMA stimulation (data not shown). Although inhibiting de novo protein synthesis with CHX significantly promotes the loss of PKC␣ in FADD ϩ/ϩ MEFs in response to PMA, CHX had no significant effect on accumulated PKC␣ in FADD Ϫ/Ϫ MEFs (Fig. 1C). These data suggest that FADD is involved in posttranslational regulation of cPKC.
To confirm that the increased PKC␣ protein levels was a consequence of FADD deletion, we reintroduced a FADD expression plasmid into FADD Ϫ/Ϫ MEFs. Re-expression of FADD restored the PMA-induced PKC␣ degradation in FADD Ϫ/Ϫ MEFs (Fig. S1).
FADD Regulates cPKC TM and HM Phosphorylation-Previous studies have indicated that both TM and HM phosphorylation of PKC␣/␤ are important for protein stability (29 -31). Therefore, we analyzed TM and HM phosphorylation of cPKC in FADD Ϫ/Ϫ MEFs. Consistent with the elevated protein level, phospho-TM and phospho-HM of PKC␣/␤ were significantly higher in FADD Ϫ/Ϫ MEFs than in FADD ϩ/ϩ MEFs (Fig. 1B).
To differentiate the effect of FADD deficiency on the levels of PKC␣ protein versus that of phosphorylation, we treated cells with PMA in a short-term manner (3 h) with higher concentrations (500 ng/ml and 1000 ng/ml) to induce rapid phosphorylation loss without affecting protein level. Strikingly, TM dephosphorylation of PKC␣/␤ was largely inhibited in FADD Ϫ/Ϫ MEFs, whereas HM dephosphorylation was comparable ( Fig. 2A). These data suggest that FADD is required for TM dephosphorylation of PKC␣/␤ but less important for HM dephosphorylation.
mTORC2 has been shown to be required for cPKC TM and HM phosphorylation (17,18). Therefore, we evaluated whether TORC2 contributes to the increased TM and HM phosphorylation in FADD Ϫ/Ϫ MEFs. This is similar to other reports (17,18), although inhibition of mTORC2 by prolonged rapamycin treatment showed an insignificant effect on total cPKC protein level. Indeed, it reduced TM and HM phosphorylation in FADD ϩ/ϩ MEFs (Fig. 2B). In contrast, rapamycin had no effect on TM and HM phosphorylation in FADD Ϫ/Ϫ MEFs (Fig. 2B). In addition, heat shock protein 90 (HSP90) has been reported to protect dephosphorylated PKC␣ from degradation (39). The HSP90 inhibitor 17-AAG promoted TM and HM dephosphorylation in FADD ϩ/ϩ MEFs, whereas it had no significant effects on phospho-TM and phospho-HM in FADD Ϫ/Ϫ MEFs (Fig. 2B). These experiments suggest that the persistent phosphorylation of cPKCs in FADD Ϫ/Ϫ MEFs is not due to increased phosphorylation.
To confirm the specific effects of FADD deletion on TM and HM phosphorylation in FADD Ϫ/Ϫ MEFs, we reintroduced a FADD plasmid into FADD Ϫ/Ϫ MEFs. Consistent with the abovementioned observations, restoration of FADD expression reduced PKC␣ protein levels. Furthermore, FADD expression reduced TM phosphorylation upon PMA treatment. Similarly, HM phosphorylation was also decreased in FADD-complemented FADD Ϫ/Ϫ MEFs (Fig. 2C).
FADD Regulates cPKC Stability-Phosphorylation of cPKC is known to provide resistance to degradation (40). Because cPKC is highly phosphorylated in FADD Ϫ/Ϫ MEFs, we explored whether the accumulated cPKC was due to increased protein stability in FADD Ϫ/Ϫ MEFs. We treated cells with CHX to monitor PKC␣ degradation. CHX reduced PKC␣ protein levels in FADD ϩ/ϩ MEFs but had no significant effect on accumulated PKC␣ in FADD Ϫ/Ϫ MEFs (Fig. 3A). This result indicates that endogenous PKC␣ is resistant to degradation in the absence of FADD. It has been well established that mature PKC␣ is phosphorylated constitutively, stable, and localized in the detergent-soluble compartment. Upon dephosphorylation, PKC␣ became detergent-insoluble (36). Most of the accumulated endogenous PKC␣ was present in the detergent-soluble supernatant, consistent with the highly phosphorylated status of PKC␣ in FADD Ϫ/Ϫ MEFs (Fig. 3B).
We then determined the effect of FADD on the stability of the TM and HM phosphorylation mutants. We transfected wild-type PKC␤II (WT), the TM mutation (PKC␤II-T634A/ T638A/T641A), and the HM mutation (PKC␤II-S660A) into 293T cells in the absence or presence of FLAG-FADD. Consistent with previous studies (17, 18), the TM phosphorylation mutant accumulated more in the detergent-insoluble pellet than WT PKC␤II and the HM mutant (Fig. 3C), suggesting a critical role of TM phosphorylation in cPKC stability. Indeed, FADD expression promoted a significant fraction of WT PKC␤II and the HM mutant to be localized in the detergentinsoluble pellet (Fig. 3C).
FADD Regulates the Recruitment of PP2A to cPKC-A previous study has reported that TM dephosphorylation of cPKC is    JULY 27, 2012 • VOLUME 287 • NUMBER 31

JOURNAL OF BIOLOGICAL CHEMISTRY 26129
okadaic acid-sensitive, whereas HM dephosphorylation is okadaic acid-insensitive (36). Furthermore, PKC␣ dephosphorylation upon PMA treatment correlates with the presence of a membrane-associated PP2A and HM phosphorylation-defective PKC␣ can be dephosphorylated by PP2A in vitro (29,34). To further study the regulation of cPKC by PP2A, we tested if PP2Ac had any effect on cPKC stability. Overexpressed PP2Ac in 293T decreased PKC␤II distribution in the detergent-soluble supernatant and promoted its accumulation in the detergent-insoluble pellet (supplemental Fig. S2). PP2A showed a similar effect on PKC␣ (data not shown). These data indicate that PP2A promotes cPKC dephosphorylation.
To further study the effect of PP2A on TM dephosphorylation, a similar PKC␤II protein level was immunoprecipitated from control and PP2Ac-overexpressed lysates. We found that overexpression of PP2Ac promoted significant TM dephosphorylation (supplemental Fig. S3). In addition, PP2Ac also induced HM dephosphorylation (supplemental Fig. S3).
PP2A activity is mainly regulated by two mechanisms: phosphatase catalytic activity and substrate target specificity. Because no significant difference in PP2A catalytic activity was found between FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs (Fig. 4A), we examined the possibility that FADD regulates the targeting  specificity of PP2A. Interestingly, PP2Ac coprecipitated with PKC␣ in FADD ϩ/ϩ MEFs, but much less PP2Ac coprecipitated with PKC␣ in FADD Ϫ/Ϫ MEFs with or without PMA (Fig. 4, B  and C). These data indicate that FADD is required for PP2A to recruit cPKC.
FADD Controls cPKC Signaling-To examine whether enhanced cPKC phosphorylation in FADD Ϫ/Ϫ MEFs leads to increased phosphorylation of PKC substrates, we examined cPKC activity and signaling. One of the PKC substrates, MARCKS (41), was utilized to evaluate cPKC activity. MARCKS phosphorylation was induced upon a milder PMA treatment in FADD ϩ/ϩ MEFs. The increased MARCKS phosphorylation was blocked by Go6976, a cPKC-specific inhibitor, in FADD Ϫ/Ϫ MEFs. Strikingly, significantly increased MARCKS phosphorylation under both basal and PMA-stimulated conditions was observed in FADD Ϫ/Ϫ MEFs in comparison with FADD ϩ/ϩ MEFs (Fig. 5A). Consistently, enhanced serine phosphorylation of PKC substrates with or without PMA treatment was observed in FADD Ϫ/Ϫ MEFs when compared with FADD ϩ/ϩ MEFs (Fig. 5B).
FADD Phosphorylation Regulates Its Novel Function-Phosphorylation of FADD at its C terminus has been shown to regulate its non-apoptotic function (23). Thus, we were interested in exploring whether phosphorylation of FADD at its C terminus had any effect on cPKC stability. Three types of MEFs, expressing wild-type FADD (WT) and the serine 191 to alanine (FADD-A) or to aspartic acid (FADD-D) FADD mutants, were utilized to examine the effect of FADD phosphorylation on PKC␣ expression and activity. Interestingly, PKC␣ was up-regulated in FADD-D MEFs compared with that in WT and FADD-A MEFs (Fig. 6A). Furthermore, PKC␣ degradation upon lower and milder PMA treatment overnight was also reduced significantly in FADD-D MEFs, whereas the expression and degradation patterns of PKC␣ in FADD-A MEFs were comparable with that in WT MEFs (Fig. 6A). Consistent with increased levels of PKC␣, PMA-induced rapid phosphorylation of both Raf-1 and ERK in 30 min, which are known to be the downstream targets of PKC, was also significantly higher in FADD-D MEFs compared with that of the WT MEFs (Fig. 6B). Because the effect of FADD-D mutation mimics the null FADD mutation regarding PKC activation, these data suggest that phosphorylation of Ser-191 in FADD may negatively regulate the effect of FADD on PKC inactivation.
To further extend our observation in MEFs, we compared the expression of cPKC and nPKC protein levels in FADD-D mice and wild-type littermates. Interestingly, FADD-D mice contained a higher amount of PKC␣, ␤II, and ␦ in cardiac muscles than did control littermates (supplemental Fig. S4). A similar up-regulation was also observed in other tissues, such as skeletal muscles, lymphocytes, and thymocytes (data not shown). Consistent with elevated PKC activity in FADD-D mice, enhanced serine phosphorylation of PKC substrates was also observed (Fig. 6C).
To examine the interaction of FADD-D mutant with PP2Ac, we compared the interaction of PKC␤II and PP2Ac in cardiac muscles of WT and FADD-D mice. We found that the interaction of PKC␤II and PP2Ac found in WT was largely abolished in FADD-D mice (Fig. 6D). These results raise the interesting pos-sibility that FADD phosphorylation regulates the interaction between cPKC and PP2Ac. Moreover, FADD-D failed to interact with PP2Ac (Fig. 6E). Paradoxically, the interaction between FADD-D and the PKC␤II was enhanced compare with that of FADD (Fig. 6F), suggesting a critical role of phosphorylation in regulating the novel function of FADD.
FADD Regulates Cytoskeleton and Cell Motility-We explored the functional consequence of FADD phosphorylation on cell morphology and motility. Both FADD Ϫ/Ϫ MEFs and FADD-D lymphocytes have been reported to have abnormal cell morphology. They are bigger and more rounded than controls (42,43). Because cPKC plays important roles in cytoskeleton regulation and cell migration, we hypothesized that deregulated cPKC might contribute to the abnormal morphology of FADD Ϫ/Ϫ MEFs. Indeed, FADD Ϫ/Ϫ MEFs had more rounded and non-aggregated F-actin morphology and more stress fibers than the FADD ϩ/ϩ MEFs (Fig. 7A). F-actin disassembly is induced rapidly upon PMA treatment. Increased and enhanced lamellipodia accumulation was observed in FADD Ϫ/Ϫ compared with FADD ϩ/ϩ MEFs treated with PMA, which was abolished by Go6976 (Fig. 7A).
Next, we characterized the motility of FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs using a wound closure assay. We found that PMA-stimulated FADD Ϫ/Ϫ MEFs but not WT MEFs were able to close the wound area after 24 h, suggesting that FADD Ϫ/Ϫ MEFs are more active in migration than that of WT MEFs (Fig.   FIGURE 7. FADD modulates cell morphology, cytoskeleton reorganization, and cell motility. A, FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs were cultured in serum-free medium for 24 h and then treated with 100 ng/ml PMA for 2 h or PMA plus 5 M Go6976. F-actin was visualized with Texas Red-X phalloidin. Scale bar ϭ 20 m. B, wound closure analysis of FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs. MEFs were cultured in serum-free medium for 24 h and then treated with 100 ng/ml PMA for 22 h. C, quantification of the Transwell assay of FADD ϩ/ϩ and FADD Ϫ/Ϫ MEFs. Cells treated with 5% FBS for 5 h. MEFs were cultured in serum-free medium for 24 h, and 5 M Go6976 was added 2 h before FBS treatment. Cells were counted from 5 or 6 equal areas. **, p Ͻ 0.01; ***, p Ͻ 0.005; Student's t test. 7B). The highly active migrating behavior of FADD-deficient MEFs was further analyzed using a transwell assay that revealed that FADD Ϫ/Ϫ MEFs were approximately 10 times higher active in migration than WT MEFs. The increased cPKC activity is likely to play a major role in the highly migratory behavior of FADD Ϫ/Ϫ MEFs as the addition of Go6976 largely inhibited the increased migration ( Fig. 7C and supplemental Fig. S5). Collectively, these results suggest that FADD is an important component of the signaling networks that regulate cytoskeleton and cell motility.
FADD Phosphorylation Regulates Cytoskeleton and Cell Mobility-Similar to that of FADD Ϫ/Ϫ MEFs, FADD-D MEFs also had abnormal morphology and enhanced formation of stress fibers, whereas the morphology of FADD-A MEFs were comparable with that of WT MEFs (Fig. 8A). Enhanced lamellipodia formation upon PMA treatment was also observed in FADD-D MEFs compared with in FADD-A and WT MEFs (Fig.  8A).
Next, we examined the effect of FADD-D mutation on cell motility. We found that FADD-D MEFs closed the wound much faster than those of WT or FADD-A MEFs (Fig. 8B). Furthermore, the accelerated migration was abolished by Go6976 (Fig. 8B). In the transwell assay, FADD-D MEFs also migrated significantly faster than WT MEFs (supplemental Fig.  S6). Quantitative analysis of FADD-D MEFs revealed a 20-fold increase in cell migration (Fig. 8C).
Consistent with the results from MEFs, both mesenteric lymphocytes and splenocytes from FADD-D mice also demonstrated accelerated chemokine-induced migration (Fig. 8, D  and E). A previous study indicated that cPKC promotes FADD phosphorylation in neutrophils treated with GM-CSF (28). We found that FADD phosphorylation was also induced by SDF-1 and FMLP (formyl-methionyl-leucyl-phenylalanine) in a cPKC-dependent manner (Fig. 8F). Collectively, these results suggest that FADD phosphorylation promotes cytoskeleton reorganization, cell migration, and chemotaxis.

DISCUSSION
The phosphorylation of three conserved sites (A-loop, TM, and HM) in PKC plays a critical role in its stability and activity (44). Endogenous PKC degradation is primed by dephosphorylation at these three sites. However, the molecular mechanisms that regulate dephosphorylation of PKCs remain largely unknown. In this study, we present that the apoptotic adaptor FADD is required for cPKC TM dephosphorylation. FADD also affected HM dephosphorylation. FADD is required for TM dephosphorylation induced by PMA, which mimics endogenous phobol esters such as diacylglycerol and Ca 2ϩ . PKC␣ and PKC␤II are resistant to PMA-dependent degradation, which leads to their accumulation in FADD Ϫ/Ϫ cells. Because the expression of FADD is also induced by PMA (Fig. 1B), induction of FADD in response to PMA may serve to negatively regulate cPKCs after their activation.
Ser-191 phosphorylation of FADD is thought to have an insignificant effect on receptor-mediated apoptosis but to dramatically inhibit cell proliferation and differentiation (27). The molecular mechanisms of these effects are unknown. Here, we presented a molecular model for how Ser-191 phosphorylation regulates the novel function of FADD. The mutant mimicking constitutive phosphorylation (FADD-D) had a decreased interaction with PP2Ac, which then resulted in an impaired interaction between PP2Ac and PKC␤II. These data suggest that Ser-191 phosphorylation abolishes the novel "adaptor" function of FADD. Interestingly, consistent with a previous report (28), Ser-191 phosphorylation of FADD was induced by chemokines in a cPKC-dependent manner, suggesting that Ser-191 is a potential target for cPKC to amplify its own signaling output.
Previous studies proved that caspase family proteases such as caspase-3, caspase-8, and caspase-11 regulate cell migration through distinct mechanisms (45)(46)(47). Our study revealed an interesting role of FADD and its phosphorylation in cell migration and chemotaxis. As an apoptotic adaptor protein, FADD is believed to be down-regulated in cancer cells to evade apoptosis. Paradoxically, FADD has been found overexpressed in many tumors, such as head and neck squamous cell carcinoma, oral squamous cell carcinoma, ovarian carcinoma, and lung adenocarcinomas (24, 48 -50). Moreover, FADD phosphorylation has been demonstrated up-regulated in tumors such as oral squamous cell carcinoma, lung adenocarcinomas, and gastric cancer and is associated with a poor outcome (26,49,51). Our study indicates that FADD phosphorylation might promote tumor progression, such as metastasis, through inducing PKC signaling.
The results from this study could explain how FADD deficiency or constitutive phosphorylation result in disorders of cell morphology, cytoskeleton, and cell motility. cPKC plays critical roles in cytoskeleton organization via phosphorylating numerous substrates, such as MARCKS, adducin, and fascin, to regulate F-actin organization (10). F-actin formation is enhanced dramatically under FADD-deficient conditions or in the presence of a FADD mutant that mimics constitutive phosphorylation. We showed that this enhancement was inhibited by a cPKC inhibitor, suggesting that both FADD and its phosphorylation are crucial for cytoskeleton organization. Consistent with the observations that PKC␣ overexpression leads to larger cell sizes, enhanced stress fibers, more lamellipodia, and extensive actin fibers (52), similar changes were also observed in FADD Ϫ/Ϫ MEFs. These data indicate that FADD is important for cell morphology and the maintenance of F-actin organization by regulating cPKC.
A schematic framework of cPKC regulation by FADD is presented in supplemental Fig. S7. We propose that FADD acts to negatively regulate PKC dephosphorylation, stability, and signaling, ultimately controlling cytoskeleton organization and cell migration. Upon phosphorylation at Ser-191, FADD loses contact with PP2A. cPKC then dissociates from PP2A. The escape of cPKC from dephosphorylation and degradation by PP2A accelerates cytoskeleton turnover and enhances cell motility.