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FAST Is a Survival Protein That Senses Mitochondrial Stress and Modulates TIA-1-Regulated Changes in Protein Expression

Division of Rheumatology, Immunology, and Allergy, Brigham and Women's Hospital, Boston, Massachusetts

Received 24 May 2004/ Returned for modification 6 July 2004/ Accepted 15 September 2004

	ABSTRACT

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The Fas-activated serine/threonine phosphoprotein (FAST) is tethered to the outer mitochondrial membrane, where it interacts with BCL-X_L (17). Here we show that RNA interference-mediated knockdown of endogenous FAST results in apoptosis, whereas overexpressed recombinant FAST inhibits Fas- and UV-induced apoptosis, indicating that FAST is a survival protein. The antiapoptotic effects of FAST are regulated by interactions with the translational silencer TIA-1: a FAST mutant lacking its TIA-1-binding domain does not inhibit apoptosis, and overexpressed recombinant TIA-1 inhibits the antiapoptotic effects of FAST. Because the antiapoptotic effects of FAST require ongoing protein synthesis, we hypothesized that FAST might function by preventing TIA-1-mediated silencing of mRNAs encoding inhibitors of apoptosis. Consistent with this hypothesis, FAST promotes the expression of cotransfected reporter proteins, a process that requires its TIA-1-binding domain and is inhibited by overexpressed recombinant TIA-1. More compellingly, recombinant FAST increases the expression of endogenous cIAP-1 and XIAP, but not GAPDH, in transfected HeLa cells. Because FAST is released from mitochondria in cells undergoing Fas- or UV-induced apoptosis, we propose that FAST serves as a sensor of mitochondrial stress that modulates a TIA-1-regulated posttranscriptional stress response program.

	INTRODUCTION

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We have identified the RNA-binding proteins TIA-1 and TIAR as downstream effectors of the PKR-eukaryotic translation initiation factor 2 subunit (eIF2) translational control pathway (15). In cells subjected to environmental stress, PKR-induced phosphorylation of the translation initiation factor eIF2 reduces the concentration of eIF2/GTP/tRNAi^Met, the ternary complex that loads the initiator tRNA onto the small ribosomal subunit. Under these conditions, TIA-1 promotes the assembly of a noncanonical 48S preinitiation complex that inhibits protein translation (2). The PKR/eIF2/TIA-1 pathway controls both protein synthesis and cell survival. Overexpression of PKR (9), a phosphomimetic mutant of eIF2 (29) or TIA-1 (14, 32) inhibits protein translation and promotes apoptotic cell death. In contrast, dominant-negative mutants of PKR or a nonphosphorylatable mutant of eIF2 promote translation and inhibit apoptosis (3, 37).

Just as translational arrest is linked to apoptotic cell death, enhanced translation is linked to malignant transformation. Overexpression of translation initiation factor eIF4E in NIH 3T3 cells is sufficient to induce cellular transformation (16). Moreover, translation initiation factor eIF4E is overexpressed in a variety of human cancers, including breast, lung, and colon (25). The signaling cascades that regulate the ability of eIF4E to initiate translation also play a prominent role in oncogenesis. AKT, a kinase activated in many cancers, indirectly activates eIF4E and enhances protein translation (36). AKT indirectly activates mTOR, another kinase that activates eIF4E, and enhances protein translation. Inhibitors of mTOR (e.g., rapamycin) are emerging as important chemotherapeutic agents (36). Taken together, these results support the concept that regulation of protein translation plays a critical role in regulating cellular proliferation and cell death.

Mitochondria also play a critical role in determining whether cells live or die. BCL-2 family members that promote cell survival (e.g., BCL-2 and BCL-X_L) or cell death (e.g., BAK) are concentrated at the outer mitochondrial membrane (7). Interactions between these proteins regulate a permeability transition pore that allows the release of cytochrome c, AIF, Smac/DIABLO, and Omi, proteins that collectively promote apoptotic cell death (26). In Jurkat T cells, apoptosis triggered by ligation of the Fas receptor is dependent upon a mitochondrial activation pathway (4). Fas ligation results in the activation of caspase-8, which cleaves the BH3-only protein BID. Truncated BID (tBID) is translocated from the cytosol to the mitochondrial membrane, where it interacts with BCL-2 and BCL-X_L (5). When the neutralizing capacity of BCL-2 and BCL-X_L is exceeded, tBID targets the proapoptotic proteins BAX and BAK, allowing the release of apoptotic effectors from mitochondrial stores (26). The release of smac/DIABLO promotes apoptosis by inhibiting IAP proteins, a family of E3 ligases that directly and indirectly inhibit the activation of apoptotic caspases (20). Tian et al. previously described a TIA-1-interacting protein (33) that resides at the outer mitochondrial membrane in association with BCL-X_L (17). This Fas-activated serine/threonine phosphoprotein (FAST) is tethered to mitochondria by a lysine/arginine-rich domain at its carboxyl terminus (17). Although FAST is constitutively phosphorylated on serine and threonine residues (33), it is rapidly dephosphorylated in Jurkat cells treated with anti-Fas antibodies. This result led us to propose that FAST may be involved in a signaling cascade that regulates apoptotic cell death (33).

Here we show that FAST is a survival protein that constitutively suppresses apoptotic cell death. The full antiapoptotic effects of FAST require active NF-B and ongoing protein synthesis, suggesting that FAST can promote the expression of antiapoptotic proteins, some of which are expressed in an NF-B-dependent manner. FAST increases, and TIA-1 reduces, the expression of cotransfected reporter proteins. TIA-1 also inhibits the ability of FAST to inhibit apoptosis. Most importantly, recombinant FAST increases the expression of endogenous inhibitors of apoptosis (i.e., cIAP-1 and XIAP) in HeLa transfectants, providing a possible mechanism for its antiapoptotic effects. Thus, interactions between FAST and TIA-1 influence both protein expression and susceptibility to apoptosis. Because FAST is displaced from mitochondria in cells undergoing Fas- or UV-induced apoptosis, we propose that FAST serves as a sensor of mitochondrial stress that promotes cell survival by enhancing the expression of antiapoptotic proteins.

	MATERIALS AND METHODS

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Cells, antibodies, and reagents. COS-7 cells and HeLa cells were obtained from the American Type Culture Collection. Cells were maintained in 10% fetal bovine serum (FBS) in Dulbecco's modified Eagle medium (DMEM). The preparation of affinity-purified rabbit polyclonal antisera reactive with FASTN was described previously (17). Antibodies obtained from commercial sources include antihemagglutinin (anti-HA) (murine monoclonal antibody clone 16B12, immunoglobulin G1; Berkeley Antibody Co.), anti-FLAG (murine monoclonal antibody clone; Sigma Chemical Co., St. Louis, Mo.), anti-BCL-X_L (rabbit polyclonal and mouse monoclonal; Santa Cruz Biotechnology, Inc.), anti-Myc (rabbit polyclonal; Santa Cruz Biotechnology, Inc.), anti-active caspase 3 (rabbit polyclonal; Promega), rabbit polyclonal anti-cIAP-1 (R and D), mouse monoclonal anti-XIAP (Stressgen), mouse monoclonal anti-GAPDH (Research Diagnostics), and anti-ß-galactosidase (mouse monoclonal; Promega). Isotype-specific secondary antibodies (multiple labeling grade) were obtained from Jackson ImmunoResearch Labs, West Grove, Pa. Hoechst dye no. 33258 and other chemicals were obtained from Sigma.

Plasmid constructions. The construction of expression vectors encoding full-length and mutant FAST were described previously (17). pMT2-HA-TIA1, pMT2-HA-TIA1-RRM, and pMT2-HA-TIA-1-PRD (previously designated TIA-1RRM) were described previously (14). The full-length coding regions of FAST and TIA-1 were also subcloned into the pcDNA3-FLAG vector. Briefly, FAST and TIA-1 were amplified by PCR with overhanging ends containing BglII/EcoRI and BamHI/EcoRI sites, respectively, and then were digested with the corresponding restriction enzymes and inserted into pcDNA3-FLAG vector predigested with BamHI/EcoRI. The pcDNA3-FLAG-BCL-X_L construct was a gift from Tom Chittenden (ImmunoGen, Inc.). Plasmid pCMV4-IBN was a kind gift from Mark Boothby (Vanderbilt University). pcDNA3-ß-gal was obtained from Invitrogen.

Western blot analysis. Whole-cell extracts were separated on 4 to 20% gradient gels, transferred to nitrocellulose, and probed with the indicated antibodies by using previously described methods (33).

Transfections and immunoprecipitations. Cells were transfected with SuperFect (QIAGEN, Valencia, Calif.) for immunofluorescence microscopy or Lipofectamine 2000 (Invitrogen) for immunoprecipitation and Western blotting analysis according to the manufacturer's instructions. Cells cultured in 6-well plates (2 x 10⁵ to 3 x 10⁵ cells/well plated 20 h before transfection) were exposed to DNA complexes for 5 h, trypsinized, and replated onto parallel plates for both immunofluorescence (24-well plates containing 11-mm-diameter coverslips) and Western blotting (12-well plates). For immunoprecipitations, cells were transfected in 6-well plates as described above without replating. After 28 h, cells were solubilized in NP-40 lysis buffer (1% NP-40, 150 mM NaCl, 1 mM EDTA, 50 mM Tris, pH 7.8). Lysates were precleared with protein A-Sepharose (Amersham Pharmacia Biotech, Piscataway, N.J.) in 150 µl of NP-40 lysis buffer for 1 h. Subsequently, precleared lysates were incubated with the antibody-protein A-Sepharose complex in 150 µl of NP-40 lysis buffer for 1 h, washed three times, and then boiled in sodium dodecyl sulfate (SDS) sample buffer for separation on a 4 to 20% polyacrylamide gradient gel (Invitrogen). Following transfer to nitrocellulose membranes, the resolved proteins were revealed by probing with the indicated antibodies.

Immunofluorescence. Cells were plated on 11-mm-diameter glass coverslips on 24-well plates. At various time points after transfection the cells were fixed in 2 to 4% paraformaldehyde in phosphate-buffered saline (PBS) for 10 min, immersed in –20°C methanol for 10 min, rinsed in PBS, and incubated in blocking buffer (5% normal horse serum in PBS) for 1 h before addition of primary antibodies. Cells were incubated with the indicated antibodies (anti-HA was used at 2.5 µg/ml, anti-ß-galactosidase was used at 2.3 µg/ml, and anti-active caspase 3 was used at a 1:1,000 dilution) for 1 h, washed several times in PBS, and incubated for 1 h with diluted isotype-specific secondary antibodies (1:200 for Cy2- or Cy5-labeled secondary antibodies and 1:2,000 for Texas red-labeled or Cy3-labeled secondary antibodies) in blocking solution supplemented with Hoechst dye. Cells were viewed using a Nikon Eclipse 800 microscope equipped with epifluorescence and appropriate filter sets optimized to detect the specific fluorochromes used. Images were digitally captured using a CCD-SPOT RT digital camera and then were merged and compiled using Adobe Photoshop software.

TUNEL assay. Cells were plated on 11-mm-diameter glass coverslips in 24-well plates and were cultured in the absence or presence of anti-Fas antibody (7C11 was used at 1:200 from culture supernatant, which was predetermined to saturate the Fas receptor; a gift from Michael Robertson, University of Illinois). Cells were then fixed in 4% paraformaldehyde in PBS for 10 min, followed by immersion in –20°C methanol for 10 min. After rehydration in PBS, cells were washed with TdT buffer (Roche) for 5 min and then were incubated with terminal transferase-mediated dUTP nick end labeling (TUNEL) reaction mix (TdT buffer, 20 nM dUTP-biotin, 0.15 µl of terminal transferase) (Roche) for 1 h at 37°C. The reaction was stopped by addition of a solution containing 20 mM sodium citrate and 300 mM NaCl. Cells were then incubated in blocking buffer for 20 min prior to the addition of streptavidin-fluorescein isothiocyanate (Fisher) at 1:1,000 in blocking buffer for 1 h. Cells were then further incubated with anti-HA, anti-caspase 3, and Hoechst dye; washed; and mounted for immunofluorescence microscopy.

Apoptosis assays. Transfected cells were cultured for 24 to 40 h prior to treatment with apoptotic inducers. The following apoptotic inducers were used: anti-Fas antibody 7C11 (1:200 dilution from culture supernatant titrated to give maximal induction of apoptosis) for 20 h, anti-Fas antibody plus cycloheximide (0.025 µg/ml) for 20 h, and UV irradiation (10 mJ/cm²) followed by recovery for 1 to 2 h. After treating cells with apoptotic inducers, cells were processed for immunofluorescence analysis and TUNEL assay as described above. The morphological scoring of individual transfectants was done blindly. At least 200 cells per experiment were scored for the presence or absence of active caspase-3, nuclear condensation, and DNA fragmentation. The data presented represent means of 3 to 10 independent experiments. The Student's paired t test was used to compare the percentage of transfected cells exhibiting these morphological changes to those of vector controls.

Cell fractionation. COS-7 or HeLa cells in log phase were harvested by scraping, centrifuged, and resuspended in detergent-free buffer (200 mM mannitol, 70 mM sucrose, 1 mM EGTA, 10 mM HEPES, pH 7.5) containing protease inhibitors (phenylmethylsulfonyl fluoride, leupeptin, aprotinin, and benzamidine) and 14.0 µM 2-mercaptoethanol. Cells were disrupted by shearing (30 times with a 26-guage needle) until cell breakage was about 90% as assessed by phase-contrast microscopy. Nuclei were pelleted by centrifugation at 1,300 x g in a refrigerated microcentrifuge for 5 min. Heavy membrane fractions containing mitochondria (referred to as the P20 fraction) were prepared by centrifuging the resulting supernatants at 14,000 rpm (20,000 x g) for 20 min. The corresponding supernatant is referred to as the S20 fraction. The relative purity of these fractions was previously reported (17).

RNA interference (RNAi). Coding sequences for small interfering RNAs (siRNAs) with a G+C ratio of 45 to 55% were analyzed by BLAST search to ensure that they did not have significant sequence homology with other genes. To generate mammalian expression vectors expressing human FAST-specific siRNA, we cloned double-stranded DNA oligonucleotides into pSuppressor-Neo vector exactly as described by the manufacturer (Imgenex). The sequences of the sense strands are as follows: ACGCAACTCAGCAGCAAGGTGgagtactgCACCTTGCTGCTGAGTTGCGT (hFASTsiRNA-1) and GGGTTGGAAGCTGCTCTAAGCgagtactgGCTTAGAGCAGCTTCCAACCC (hFAST siRNA-2) (gene-specific sequences are in capitals and hairpin sequences are underlined). pSuperessor2 vector expressing a scramble sequence (sense strand, GCGCGCTTTGTAGGATTCGgagtactgCGAATCCTACAAAGCGCGC) was used as a negative control.

COS-7 cells were transfected with recombinant HA-FAST together with the individual pSuper-siFAST constructs by using Lipofectamine 2000. After 48 h, total cell lysates were analyzed by Western blotting with anti-HA antibody. These same vectors were transfected into HeLa cells by using Lipofectamine 2000. After 48 h, cells were solubilized in 1% NP-40 lysis buffer and were centrifuged at 10,600 x g in a desktop centrifuged for 5 min before analyzing supernatants by Western blotting using anti-FASTN antibody to quantify the expression of endogenous FAST.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
FAST is a constitutively active survival factor. FAST is a mitochondria-associated, BCL-X_L-interacting protein that has been proposed to regulate apoptotic cell death (17, 33). To determine whether FAST can regulate apoptosis, we constructed vector-based siRNAs designed to reduce the expression of endogenous FAST. Sequences conforming to published guidelines for targeted knockdown of selected mRNAs (34) were inserted into the pSuppressor2 vector and were cotransfected with HA-FAST into COS-7 cells. After 48 h, cells were processed for Western blotting analysis to quantify the expression of HA-FAST. We identified two different vector-based siRNAs (siFAST-1 and siFAST-2) that significantly and reproducibly lower the expression of HA-FAST (Fig. 1A). We then transfected HeLa cells with siFAST-1 or a negative control siRNA and quantified the expression of endogenous FAST by Western blotting analysis. As shown in Fig. 1B, siFAST-1 reduces the expression of endogenous FAST in HeLa cells. The reduction is less than that in COS-7 cells, because not all cells receive the siRNA in this transient transfection experiment. To selectively visualize transfected cells, we cotransfected HeLa cells with the siRNA vectors together with a vector encoding ß-galactosidase. After 48, 56, or 72 h, cells were processed for two-color immunofluorescence microscopy to visualize ß-galactosidase and active caspase-3 (Fig. 1C). HeLa cells transfected with si-FAST-1 (Fig. 1C) or si-FAST-2 (data not shown) exhibit cytoplasmic and nuclear condensation and activation of caspase 3. These results are quantified in Fig. 1D. These results reveal that FAST is a survival protein that prevents the spontaneous (or transfection-induced) activation of caspase 3 and apoptosis.

View larger version (88K): [in this window] [in a new window]   FIG. 1. Knocking down FAST results in apoptosis. (A) COS-7 cells were transfected with pMT2-HA-FAST together with a vector-based negative control RNAi (pSuppressor2-SiNC), FAST RNAi-1 (pSuppressor2-SiFAST-1), or FAST RNAi-2 (pSupressor2-SiFAST-2). After 48 h, cells were processed for Western blotting analysis to quantify the expression of recombinant HA-FAST. (B) HeLa cells were transfected with either negative control RNAi (SiNC) or FAST RNAi (SiFAST-1). After 48 h, cells were processed for Western blotting analysis to quantify the expression of endogenous FAST. (C) HeLa cells were transfected with pcDNA3-ß-galactosidase together with either negative control RNAi (SiNC) or FAST RNAi (siFAST-1 or siFAST-2) before being processed for immunofluorescence microscopy using anti-ß-galactosidase, anti-active caspase 3, or Hoechst dye. Arrows point out healthy transfected cells. Arrowheads point out transfected cells that are undergoing apoptosis. Size bar, 20 µm. (D) The mean percentages (±standard errors; n = 3) of transfected cells (revealed using anti-ß-galactosidase) that exhibit active caspase-3 are presented as a bar graph. Calculated P values for selected comparisons are shown. ß-gal, ß-galactosidase.

View larger version (111K): [in this window] [in a new window]   FIG. 2. FAST inhibits Fas- and UV-induced apoptosis. (A) HeLa cells were mock transfected or transfected with vectors encoding HA-FAST or ß-galactosidase, cultured in the absence (untreated) or presence of anti-Fas antibody (FAS) before being processed for immunofluorescence microscopy using anti-HA, anti-ß-galactosidase, anti-active caspase 3, and Hoechst dye. Arrows point out cells undergoing Fas-induced caspase-dependent apoptosis. Arrowheads point out FAST transfectants in which caspase 3 is not activated. Size bar, 20 µm. (B) HeLa cells were mock transfected or transfected with either FAST or ß-galactosidase (ß-gal), cultured in the presence of anti-Fas antibody, and then processed for TUNEL analysis (red) and immunofluorescence (anti-HA, green; anti-active caspase 3, blue) or Hoechst staining. Arrows point out untransfected cells or ß-galactosidase-transfected cells. Arrowheads point out FAST transfectants. (C) The mean percentages (±standard errors; n = 3) of transfected cells (vector control, HA-FAST, HA-FASTN, or HA-FASTC; revealed using anti-HA or anti-ß-galactosidase) cultured under the indicated conditions that exhibit active caspase 3 are presented as a bar graph. Calculated P values for selected comparisons are shown.

View larger version (35K): [in this window] [in a new window]   FIG. 3. (A) Stress stimuli displace endogenous FAST from mitochondria. HeLa cells were left untreated or were treated with UV irradiation (10 mJ/cm2 followed by 0.5 or 1 h recovery) or anti-Fas antibody (1:200 dilution from culture supernatants) for 6 h before being processed to obtain pellets enriched in mitochondria (P20) and corresponding supernatants (S20). Individual fractions were processed for Western blotting analysis with anti-FASTN antibody or anti-BCL-XL antibody. (B) Fas ligation interrupts FAST/BCL-XL interaction. HeLa cell extracts prepared from cells cultured in the absence or presence of anti-Fas antibody were processed for coimmunoprecipitation with either rabbit anti-BCL-XL antibody or an isotype-matched control antibody (rabbit anti-Myc). Immunoprecipitates were then processed for Western blotting analysis with anti-FAST-N antibody or mouse anti-BCL-XL antibody.

View larger version (31K): [in this window] [in a new window]   FIG. 4. Identification of FAST/TIA1 interaction sites. (A) Schematic depiction of HA-FASTN and HA-FASTC truncation mutants. MTD, mitochondrial tethering domain; BH3, BCL2 homology 3-related domain. (B) Schematic depiction of HA-TIA-1 truncation mutants. 1, 2, 3, RNA-recognition motifs; PRD, prion-related domain. (C) COS-7 cells were cotransfected with pcDNA3-FLAG-TIA1 and the indicated HA-FAST truncation mutants. After 28 h, cells were processed for coimmunoprecipitation analysis with mouse anti-HA antibody followed by Western blotting analysis with mouse anti-FLAG antibody, followed by mouse anti-HA antibody. Lysates from transfected cells were analyzed by Western blotting with anti-FLAG antibody (load). (D) COS-7 cells were cotransfected with pcDNA3-FLAG-FAST and the indicated HA-TIA1 truncation mutants. Lysates from transfected cells were immunoprecipitated with anti-HA antibody and then were sequentially blotted with anti-FLAG antibody and anti-HA antibody. Lysates from transfected cells were analyzed by Western blotting with anti-FLAG antibody (load). FL, FLAG.

View larger version (83K): [in this window] [in a new window]   FIG. 5. TIA-1 inhibits the antiapoptotic effects of FAST. HeLa cells were transfected with the indicated constructs, cultured in the absence (untreated) or presence (Fas) of anti-Fas antibody, and then processed for immunofluorescence microscopy using anti-HA (or anti-ß-galactosidase), anti-active caspase 3, or Hoechst dye. The mean percentages (±standard errors; n = 3) of transfected cells (revealed using anti-HA or anti-ß-galactosidase) cultured under the indicated conditions that exhibit active caspase 3 are presented as bar graphs. Calculated P values for selected comparisons are shown.

View larger version (44K): [in this window] [in a new window]   FIG. 6. FAST enhances the expression of cotransfected ß-galactosidase. The left panel shows COS-7 cells cotransfected with a ß-galactosidase reporter together with pMT2 alone, pMT2-HA-FAST, pMT2-HA-TIA-1, or pMT2-HA-TIA-1-PRD. After 48 h, cells were processed for Western blotting analysis to quantify the expression of ß-galactosidase (ß-gal). The right panel shows COS-7 cells cotransfected with a ß-galactosidase reporter together with pMT2-HA-FAST and increasing amounts of pMT2-HA-TIA-1 (5:1, 2:1, 1:1). After 48 h, cells were processed for Western blotting analysis to quantify the expression of ß-galactosidase and the expression of recombinant TIA-1 and FAST.

View larger version (41K): [in this window] [in a new window]   FIG. 7. FASTC increases reporter gene expression and is regulated by BCL-XL. (A) COS-7 cells were cotransfected with a ß-galactosidase reporter together with pcDNA3 vector and pMT2 alone, pMT2-HA-FAST, pMT2-HA-FASTN, pMT2-HA-FASTC, or pMT2-HA-FASTCBH3. After 48 h, cells were processed for Western blotting analysis to quantify the expression of ß-galactosidase. (B) COS-7 cells were cotransfected with a ß-galactosidase reporter together with pcDNA3-BCL-XL and pMT2 alone, pMT2-HA-FAST, pMT2-HA-FASTN, or pMT2-HA-FASTC.

View larger version (46K): [in this window] [in a new window]   FIG. 8. Effects of siFAST-1 on ß-galactosidase expression. COS-7 cells were cotransfected with a ß-galactosidase (ß-gal) reporter together with pMT2-HA-FAST, pMT2-HA-FASTN, or pMT2-HA-FASTC and either pSupressor2-siNC (lanes 1 to 3) or pSupressor-2-siFAST-1 (lanes 4 to 6). After 48 h, cells were processed for Western blotting analysis to quantify the expression of ß-galactosidase (A) or individual HA-FAST constructs (B). Molecular size markers are shown at the left. Bands corresponding to ß-galactosidase, HA-FAST, and HA-FASTC are indicated by arrows.

View larger version (27K): [in this window] [in a new window]   FIG. 9. Fas ligation modulates the expression of ß-galactosidase. (A) HeLa cells were cotransfected with a ß-galactosidase reporter together with pMT2 vector, pMT2-HA-FAST, or pMT2-HA-FASTC, and then they were cultured in the absence or presence of anti-Fas antibody before being processed for Western blotting analysis to quantify the expression of ß-galactosidase (ß-gal) (upper panel), HA-FAST, and HA-FASTC (lower panel). (B) HeLa cells were transfected with negative control siRNA or siFAST-1 and cultured for 28 or 36 h in the presence of z-VAD (100 nM; Enzyme Systems Products), and then they were treated with anti-Fas antibody for 6 h or overnight, as indicated, before being processed for immunoblotting analysis to quantify the expression of ß-galactosidase and endogenous GAPDH.

Evidence that FAST modulates the NF-B-dependent survival pathway. Although FASTN is not tethered to mitochondria, it binds to TIA-1, enhances reporter protein expression, and inhibits apoptosis. The antiapoptotic effects of FAST are unlikely to target mitochondrion-associated regulators of apoptosis. The correlation between TIA-1 binding, reporter protein expression, and inhibition of apoptosis suggests that FAST might inhibit TIA-1-induced translational silencing directly and that the antiapoptotic effects of FAST may result from increased expression of one or more antiapoptotic proteins. In HeLa cells, Fas ligation leads to the NF-B-dependent transcription of several caspase inhibitors (e.g., c-IAP-1, c-IAP-2, and c-FLIP) (19). Pharmacologic inhibitors of translation (e.g., cycloheximide) potentiate Fas-induced apoptosis by blocking the expression of these caspase inhibitors (19). We therefore examined the effects of cycloheximide and mutant IBN (an IB truncation mutant that functions as a dominant inhibitor of NK-B [6]) on Fas-induced apoptosis in FAST transfectants. As shown in Fig. 10, both cycloheximide and IBN partially reverse the FAST-mediated inhibition of caspase activation. These results support the hypothesis that the antiapoptotic effects of FAST are mediated in part by enhanced expression of NF-B-induced antiapoptotic proteins.

View larger version (61K): [in this window] [in a new window]   FIG. 10. The antiapoptotic effects of FAST require active NF-B and ongoing protein synthesis. HeLa cells were transfected with the indicated constructs and then were cultured in the absence (untreated) or presence of anti-Fas antibody (Fas), with or without cycloheximide (CHX; 0.025 µg/ml), before being processed for immunofluorescence microscopy using anti-HA (or anti-ß-galactosidase), anti-caspase 3, or Hoechst dye. The mean percentages (±standard errors; n = 3) of transfected cells (revealed using anti-HA or anti-ß-galactosidase) that exhibit active caspase-3 are presented as bar graphs. Calculated P values for selected comparisons are shown.

View larger version (49K): [in this window] [in a new window]   FIG. 11. FAST promotes the expression of cIAP-1 and XIAP in HeLa transfectants. (A) HeLa cells were transfected with cDNAs encoding a vector control or recombinant FAST. After 48 h, cells were processed for Western blotting to quantify the expression of endogenous cIAP-1, XIAP, and GAPDH. These blots are representative of three independent experiments. (B) The expression of cIAP-1 and XIAP was quantified by densitometry. Protein expression in vector transfectants was assigned a value of 1. The relative increase in expression observed in FAST transfectants is indicated as means ± standard errors (n = 3). P values were calculated using the Student's t test.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Here we report that reduced expression of endogenous FAST protein by siRNA is sufficient to induce apoptosis in HeLa cells. Conversely, overexpressed recombinant FAST is a potent inhibitor of Fas- and UV-induced apoptosis. Both Fas ligation (22) and UV irradiation (27, 28) induce the activation of caspase-8 and the cleavage of BID. We propose that FAST acts downstream of these events by serving as a sensor of BCL-2 family member dynamics at the mitochondrial membrane. In the model shown in Fig. 12, FAST resides at the outer mitochondrial membrane in association with BCL-X_L (17). In response to Fas ligation or UV irradiation, tBID and BAX move to the outer mitochondrial membrane, where they sequester BCL-X_L and release FAST from its mitochondrial tether. Consistent with this premise, FAST is displaced from mitochondria in HeLa cells subjected to Fas ligation or UV irradiation (Fig. 3A). FAST is also displaced from BCL-X_L in response to Fas ligation (Fig. 3B).

View larger version (185K): [in this window] [in a new window]   FIG. 12. Proposed mechanism by which FAST inhibits Fas-induced apoptosis.

Consistent with this model, FAST and TIA-1 are functional antagonists that interact to determine levels of protein expression. When transfected into COS-7 cells, recombinant FAST increases, and recombinant TIA-1 decreases, the expression of cotransfected ß-galactosidase (Fig. 6). In cotransfection experiments, recombinant TIA-1 reverses the ability of recombinant FAST to enhance ß-galactosidase expression (Fig. 6). Mutational analysis reveals that the functional effects of FAST require its TIA-1-binding domain: FASTN binds to TIA-1 and enhances the expression of cotransfected ß-galactosidase, whereas FASTC does not bind to TIA-1 and does not directly enhance the expression of ß-galactosidase. The functional effects of FASTC are complicated by its ability to interact with mitochondria and influence endogenous FAST (Fig. 7 and 8). These results suggest that FAST increases protein expression by binding to, and inhibiting the function of, TIA-1.

Our model further posits that FAST/TIA-1-regulated expression of survival proteins determines susceptibility to apoptosis. Once again, mutational analysis supports this contention: FASTN binds to TIA-1 and inhibits apoptosis, whereas FASTC does not bind to TIA-1 and does not inhibit apoptosis (Fig. 3). Moreover, overexpressed recombinant TIA-1 reverses the ability of recombinant FAST to inhibit apoptosis (Fig. 5).

The importance of the FAST-TIA-1 interactions is further illustrated by analysis of TIA-1 truncation mutants. Coimmunoprecipitation analysis reveals that FAST binds to the prion-related domain (TIA-1-PRD) but not the RNA-binding domain (TIA-1-RRM) of TIA-1. Both TIA-1-PRD (Fig. 6) and TIA-1-RRM enhance the expression of cotransfected ß-galactosidase (unpublished data), suggesting that either protein can act as a dominant inhibitor of endogenous TIA-1. Despite its ability to enhance protein expression, TIA-1-PRD inhibits the antiapoptotic effects of FAST (Fig. 5). These results indicate that enhanced protein expression is not sufficient for the antiapoptotic effects of FAST. Similarly, inhibition of protein synthesis by the Drosophila death effector protein, reaper, is necessary, but not sufficient, to induce apoptotic cell death in HeLa cells (31). It is possible that TIA-1-PRD inhibits a FAST-mediated antiapoptotic function that is unrelated to protein expression. Further experiments will be required to resolve this issue.

Several observations suggest that BCL-X_L regulates the function of FAST: (i) FASTC truncation mutants lacking the BCL-X_L-binding domain no longer increase the expression of cotransfected ß-galactosidase; (ii) cotransfection with BCL-X_L reduces the ability of FASTC to increase the expression of cotransfected ß-galactosidase; and (iii) Fas ligation disrupts FAST:BCL-X_L interactions. The release of FAST from the mitochondrial membrane may be analogous to the release of proapoptotic factors (e.g., cytochrome c, AIF, smac/DIABLO, and Omi) from the mitochondrial interstices (7, 26). By antagonizing the effects of these proapoptotic factors, FAST may favor survival by upregulating the expression of antiapoptotic factors.

Protein translation plays an important role in regulating apoptosis. In many cell types, Fas- and TNF-induced apoptosis is potentiated by cycloheximide-induced inhibition of protein synthesis. This appears to result from reduced translation of NF-B-induced transcripts that carry antiapoptotic genes (19). In addition, transfection of HeLa cells with the proapoptotic Drosophila proteins reaper and grim induces a general translational arrest that is required for apoptotic cell death (11, 31, 38). Thus, reaper- and grim-induced apoptosis may be mechanistically similar to stress-induced apoptosis that is mediated by the PKR/eIF2/TIA-1 pathway. Because FAST interacts with TIA-1, we hypothesized that its antiapoptotic effects might be a consequence of enhanced expression of NF-B-induced antiapoptotic proteins. Consistent with this hypothesis, the antiapoptotic effects of FAST are partially reversed by both cycloheximide and a dominant-negative inhibitor of NF-B (Fig. 10). The effects of the dominant-negative inhibitor of NF-B are significantly less than the effects of cycloheximide, suggesting that FAST might also promote the expression of proteins whose expression is independent of NF-B.

In the final step of our model (Fig. 12), we propose that FAST and TIA-1 regulate the expression of constitutive or induced survival proteins. In support of this mechanism, recombinant FAST increases the expression of endogenous cIAP-1 and XIAP, inhibitors of apoptosis that are regulated by the NF-B pathway (30) (Fig. 11). The upregulation of these inhibitors of apoptosis is at least partially selective, as FAST does not affect the expression of endogenous GAPDH. The mechanism by which FAST enhances the expression of cIAP-1 and XIAP remains to be determined. By inhibiting the function of TIA-1, FAST might increase the expression of cIAP-1 and XIAP by promoting their translation. The posttranscriptional regulation of XIAP expression is complex. Transcripts encoding XIAP also encode an internal ribosome entry site (IRES) that enhances translation in response to stress (10). Additional experiments will be required to determine whether FAST and/or TIA-1 regulate translational initiation via the IRES element and whether upregulation of cIAP-1 and XIAP are sufficient to bring about the antiapoptotic effects of FAST.

The ability of FAST to modify the Fas-induced death program suggests that it may participate in some forms of immune-mediated inflammatory disease. Inactivating mutations of Fas leads to autoimmune disease in both rodents and humans (8, 24). Interestingly, FAST is overexpressed in patients with a variety of immune-mediated inflammatory diseases, including rheumatoid arthritis, systemic lupus erythematosus, autoimmune diabetes, and multiple sclerosis (18, 21). Overexpression or misregulation of FAST could contribute to these autoimmune syndromes by delaying the onset of apoptosis, a prelude to autoimmune disease in several experimental systems (35). Taken together, the results presented here offer an explanation of how FAST overexpression might promote the onset of immune-mediated inflammatory disease.

	ACKNOWLEDGMENTS

 
We thank members of the Anderson lab for helpful discussions. We thank Natalie Gilks for making the pcDNA3-FLAG-FAST and pcDNA3-FLAG-TIA-1 constructs.

This work was supported by a fellowship from the Arthritis Foundation (W.L.), a Biomedical Science Award from the Arthritis Foundation (P.A.), and by grants from the NIH (AI50167, AI33600, and AR051472).

	FOOTNOTES

 
* Corresponding author. Mailing address: Division of Rheumatology, Immunology and Allergy, Brigham and Women's Hospital, Smith 652, One Jimmy Fund Way, Boston, MA 02115. Phone: (617) 525-1202. Fax: (617) 525-1310. E-mail: panderson{at}rics.bwh.harvard.edu.

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