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© The Rockefeller University Press, 0021-9525/1998//1479 $5.00
The Journal of Cell Biology, Volume 141, Number 7, , 1998 1479-1487

Suppression of Steady-state, but not Stimulus-induced NF-B Activity Inhibits Alphavirus-induced Apoptosis

Kuo-I Lin^*,||, Joseph A. DiDonato, Alexander Hoffmann, J. Marie Hardwick^*, and Rajiv R. Ratan^||

^* Department of Molecular Microbiology and Immunology, The Johns Hopkins University School of Public Health, Baltimore, Maryland 21205; Department of Medicine, University of California, San Diego, La Jolla, California 92093; Department of Biology, Massachusetts Institute of Technology, Boston, Massachusetts 02114; and ^|| Department of Neurology and Program in Neuroscience, Harvard Medical School and Beth Israel-Deaconess Medical Center, Boston, Massachusetts 02115

Recent studies have established cell type– specific, proapoptotic, or antiapoptotic functions for the transcription factor NF-B. In each of these studies, inhibitors of NF-B activity have been present before the apoptotic stimulus, and so the role of stimulus- induced NF-B activation in enhancing or inhibiting survival could not be directly assessed. Sindbis virus, an alphavirus, induces NF-B activation and apoptosis in cultured cell lines. To address whether Sindbis virus– induced NF-B activation is required for apoptosis, we used a chimeric Sindbis virus that expresses a superrepressor of NF-B activity. Complete suppression of virus-induced NF-B activity neither prevents nor potentiates Sindbis virus–induced apoptosis. In contrast, inhibition of NF-B activity before infection inhibits Sindbis virus–induced apoptosis. Our results demonstrate that suppression of steady-state, but not stimulus-induced NF-B activity, regulates expression of gene products required for Sindbis virus–induced death. Furthermore, we show that in the same cell line, NF-B can be proapoptotic or antiapoptotic depending on the death stimulus. We propose that the role of NF-B in regulating apoptosis is determined by the death stimulus and by the timing of modulating NF-B activity relative to the death stimulus.

MULTICELLULAR organisms use a programmed process known as apoptosis to eliminate damaged or unwanted cells during development, in adulthood, or in disease states. In some instances, cells destined to die by apoptosis must synthesize new mRNAs encoding putative death proteins for ordered self-destruction to occur. Indeed, general inhibitors of transcription and translation inhibit apoptotic death in response to a host of stimuli, even when added many hours after the onset of the death stimulus (Martin et al., 1988; Oppenheim et al., 1990; Ratan et al., 1994; Jacobson et al., 1997). A requirement for transcription in the proper execution of some types of apoptosis has stimulated a search for DNA-binding proteins known as transcription factors that are activated by apoptotic stimuli, and that govern expression of putative death proteins (Jehn and Osborne, 1997). Several apoptosis-associated transcription factors have been identified, including p53 (Lowe et al., 1993), c-jun (Estus et al., 1994; Ham et al., 1995), Nurr-77/Nor-1 (Liu et al., 1994; Woronicz et al., 1994), and interferon regulatory factor-1 (Tanaka et al., 1994).

Recent data suggests that another transcription factor, NF-B, though classically associated with immune and inflammatory responses (Baeuerle and Henkel, 1994), can also be added to the list of apoptosis-associated transcription factors. The NF-B family of transcription factors is composed of five different subunits, including p50, p52, p65/Rel A, c-Rel, and Rel-B, which can form either homodimers or heterodimers (Baeuerle and Baltimore, 1996). Overexpression of one of these NF-B subunits, c-rel, in chick bone marrow cells leads to apoptosis (Abbadie et al., 1993). These observations suggest that in some cell types, NF-B activation is sufficient to activate the apoptotic process. Additionally, inhibition of NF-B activity using B-specific transcription factor decoys inhibits Sindbis virus–induced cell death in AT-3 prostate carcinoma cells (Lin et al., 1995). Moreover, overexpression of a truncated dominant-negative form of p65/rel A inhibits serum deprivation–induced NF-B–dependent gene activation and apoptosis in human embryonic kidney cells (Grimm et al., 1996). These results identify apoptotic paradigms where NF-B activation is necessary for cell death initiation, and confirm that NF-B can act as a proapoptotic transcription factor. Indeed, several proapoptotic genes, including c-Myc (La Rosa et al., 1994), p53 (Wu and Lozano, 1994), Fas ligand (Takahashi et al., 1994), and interleukin-1 β–converting enzyme (caspase-1; Casano et al., 1994) have NF-B–binding sequences in their promoter regions.

In contrast to the aforementioned observations, NF-B activity appears to regulate genes that suppress some types of apoptosis. For example, suppression of NF-B activity in immature B cells after adding anti-IgM (Wu et al., 1996); in cells stimulated with TNF-, radiation, or daunorubicin (Liu et al., 1996; Beg and Baltimore, 1996; Wang et al., 1996; van Antwerp et al., 1996); or in liver during development (Beg et al., 1995); dramatically enhances cell death. Putative NF-B–regulated antiapoptotic genes include manganese superoxide dismutase (Wong et al., 1989) and the zinc finger protein A20 (Opipari et al., 1992). Thus, NF-B activity can play a pivotal role in triggering antiapoptotic or proapoptotic pathways; however, the precise factors that determine NF-B's ability to regulate these divergent biological outcomes remain unclear.

Under basal nonstress conditions, NF-B is sequestered in most cells in the cytoplasm by a member of the IB family of proteins: IB, IBβ, or IB (Baeuerle and Baltimore, 1988; Baeuerle and Baltimore, 1996). Binding of IB to NF-B masks nuclear localization signals on NF-B and prevents its translocation to the nucleus (Beg et al., 1992). In response to a host of stimuli, including TNF-, virus infection, lipopolysaccharide, and UV light, IB is phosphorylated, followed by its degradation via the ubiquitin–proteasome pathway (Henkel et al., 1993; Palombella et al., 1994; Thanos and Maniatis, 1995; Chen et al., 1996; DiDonato et al., 1995; DiDonato et al., 1996; DiDonato et al., 1997; Régnier et al., 1997). Degradation of IB allows free NF-B to translocate to the nucleus to influence expression of its target genes. Degradation of IB can be inhibited by mutating either serine 32 or 36 in the NH₂-terminal region of IB to alanines. (Brown et al., 1995; Traenckner et al., 1995; DiDonato et al., 1996). Overexpression of the 32A/36A NH₂-terminal mutant (IB M) is an effective molecular strategy for suppressing NF-B activation in cultured cells (Wang et al., 1996). Indeed, stable cell lines containing the superrepressor of NF-B, IB M have been generated and used to demonstrate an antiapoptotic role for NF-B activity in TNF , daunorubicin, or UV irradiation–induced apoptosis (Wang et al., 1996; van Antwerp et al., 1996). However, this approach does not distinguish whether suppression of NF-B activity must be initiated before or after the apoptotic stimulus to regulate apoptosis.

To begin to address this question, we used the alphavirus Sindbis virus, which induces apoptosis in cultured cells (Levine et al., 1993) and in the brains of newborn mice (Lewis et al., 1996). Like many other inducers of apoptosis, the precise mechanisms by which Sindbis virus (SV)¹ induces apoptosis is unknown, but many general antagonists of apoptosis, including Bcl-2 (Levine et al., 1993; Levine et al., 1996), Bcl-X_L (Cheng et al., 1996), or the antioxidant N-acetylcysteine (NAC; Lin et al., 1995) can block SV-induced death. Moreover, SV induces activation of NF-B via a classical ubiquitin–proteasome pathway many hours in advance of morphological evidence of apoptosis (Lin et al., 1998). Previous studies from our laboratory demonstrated that NF-B activity is required for cell death in AT-3 prostate carcinoma cells (Lin et al., 1995), but as with other studies, the NF-B inhibitors were present before the apoptotic stimulus was applied, and so the role of SV-induced NF-B activation in regulating apoptosis could not be directly assessed.

Recently, a recombinant form of SV has been developed as a vector to express heterologous proteins after infection, allowing their roles in SV-induced death to be examined (Cheng et al., 1996). We used this vector to generate a recombinant SV that carries the superrepressor form of IB . Such a vector can not only elicit apoptosis, but can also inhibit nuclear NF-B activity after, but not before infection. We report here that complete suppression of NF-B activation after SV infection neither suppresses nor potentiates cell death. In contrast, stable expression of a superrepressor form of IB in cell lines resulting in constitutive suppression of NF-B activation suppresses SV-induced death. These data suggest that NF-B activity induced by an apoptotic stimulus such as SV infection does not influence cell viability, while NF-B activity before SV infection is critical in regulating a proapoptotic response.

	Materials and Methods

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Culture and Viability Studies
AT-3 rat prostate carcinoma cells were cultured as previously described (Lin et al., 1995) in RPMI 1640 medium containing 10% FCS, 2 mM L-glutamine, penicillin (50 U/ml), and streptomcyin (50 µg/ml). Wild-type, p65 knockout (p65^–/–), and p50 knockout (p50^–/–) 3T3 fibroblasts or EFs (mouse embryonic fibroblasts) were cultured as previously described (Beg and Baltimore, 1996). For viability studies, 10³ AT-3 cell/well or 10⁴ mouse embryo fibroblasts/well were plated in 96-well dishes. One day after plating, SV (strain AR339) or recombinant SV (wild-type, M, or R) were added at a multiplicity of infection of 10 plaque-forming units per cell. Viability was assessed using a viability index generated by measuring the cell-associated LDH activity (Promega Corp., Madison, WI) in SV- infected cells and dividing this value by the cell-associated LDH activity in mock-infected cells. In parallel, viability was also assessed by using the metabolic label alamarBlue (Accu Med International, Chicago, IL) and by making morphological observations of cell death using phase contrast microscopy. Apoptotic cells were identified by the presence of phase bright apoptotic bodies, or by pyknosis associated with membrane blebbing. Previous studies have verified that these morphological changes induced by SV in AT-3 cells are correlated with DNA laddering in multimers of 185 bp, and hypercondensation and fragmentation of chromatin characteristic of apoptosis (Lin et al., 1995).

For the cytotoxicity experiments involving TNF (mouse; Boehringer Mannheim Corp., Indianapolis, IN), 10⁴ AT-3 Zeo or AT-3 IB Zeo cells were seeded/well in a 96-well plate; for cytotoxicity experiments involving H₂O₂, staurosporine 10³ AT-3 Zeo or AT-3 IB Zeo cells were seeded/ well in a 96-well plate. In each of these death paradigms, viability was assessed as described above.

Generation of Recombinant Sindbis Viruses Containing IB wild-type (wt), IB M, and IB R
A fragment of hemagglutinin (HA; 3x)-tagged IB wt or an HA (3x) tagged-IB with serines 32 and 36 mutated to alanines (M) was cut from the HindIII/NotI sites of the corresponding Bluescript II Ks+ plasmids (DiDonato et al., 1996). Each fragment containing IB wt or IB M was blunt end–ligated into the BstEII site of a recombinant SV vector (ds TE12Q) in forward and reverse orientations. The SV vectors containing wild-type and mutated forms of HA-IB were linearized with PvuI and transcribed in vitro with SP6 RNA polymerase (GIBCO BRL, Gaithersburg, MD). The resultant RNA transcripts were then transfected into BHK cells using 10 µg of lipofectamine (GIBCO BRL) according to the manufacturer's instructions. 24 h after transfection, recombinant viruses were harvested from the supernatant of the culture media of the transfected BHK cells. Viral titers were determined by standard plaque assays as previously described.

Electrophoretic Mobility Shift Assays (EMSAs)
Cytoplasmic and nuclear extracts were generated as previously described (Lin et al., 1995). The protein concentration was determined by BCA assay (Pierce Chemical Co., Rockford, IL). Binding reactions for EMSA were performed at room temperature for 15 min using 6–8 µg of nuclear protein and 40,000 cpm (NF-B) or 25,000 cpm (AP-1) of radiolabeled oligonucleotide. DNA–protein complexes were separated from unbound probe on native 5.3% polyacrylamide gels at 200–250 V for 2–3 h. The resultant gel was vacuum-dried and exposed on film (Eastman Kodak Co., Rochester, NY) overnight at –80°C.

Immunoblot Analysis
20 µg of protein from cytoplasmic extracts were boiled in Laemmeli buffer and electrophoresed under reducing conditions on 12% polyacrylamide gels. Proteins were then transferred to a polyvinylidene difluoride membrane (Bio-Rad Laboratories, Hercules, CA). Nonspecific binding was inhibited by incubation in Tris-buffered saline (TBST: 50 mM Tris-HCl, pH 8.0, 0.9% NaCl, 0.1% Tween 20) containing 5% nonfat dried milk for 2 h. Rabbit anti-IB antibody (C-21; Santa Cruz Biotechnology, Santa Cruz, CA) and a polyclonal antibody recognizing Sindbis virus structural proteins (a gift from Dr. Diane Griffin, The Johns Hopkins University School of Hygiene and Public Health) were diluted in 1% milk-TBST at 1:1,000. Mouse anti-HA (12 CA5, Boehringer Mannheim) monoclonal antibody was diluted 1:1,000 in 1% milk TBST. After exposure of membranes to HRP-conjugated anti-rabbit secondary antibody or HRP-linked anti-mouse secondary antibody for 1.5 h, immunoreactive proteins were detected according to the enhanced chemiluminescent protocol (Amersham Corp., Arlington Heights, IL). For quantitiave analysis of IB degradation after SV infection, secondary antibody incubation and immunocomplexes detection were performed according to the enhanced chemiluminescent fluorescence protocol (Amersham Corp.).

Generation of AT-3 Cell Lines with Enforced Expression of IBs
A HindIII/Not I fragment containing HA-tagged IB M was blunt-ended and ligated into the NheI site of an expression vector, pcDNA 3.1/Zeo (Invitrogen, San Diego, CA). 2 µg of pcDNA 3.1/HA-IB Zeo or empty vector pcDNA 3.1/Zeo was transfected into AT-3 cells (2 x 10⁵) using lipofectamine as described above. Resistant pools of clones containing the transfected plasmids were selected with Zeocin (Invitrogen Corp.) at 350 µg/ml. Approximately 30 pools of clones (AT-3 IB Zeo or AT-3 Zeo) were isolated and expanded. Expression of IB M in two independent pools of clones was verified by immunoblotting using an anti-IB antibody as described above.

Luciferase Assays
10⁵ AT-3 Zeo or AT-3 IB Zeo cells were transfected using the lipofectamine method, with 1.5 µg of SV40B-luc reporter constructs (Ting et al., 1996) along with 500 ng of pCMV-βgal plasmids. Luciferase activity was determined 30 h after transfection, and was normalized on the basis of β-galactosidase expression level. Both the luciferase assay system and β-galactosidase assay system were purchased from Promega Corp.

	Results

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Inhibition of SV-induced NF-B Activity in AT-3 Cells by Expression of IB in a Sindbis Virus Vector
To test whether SV-induced NF-B activity is required for SV-induced apoptosis, we generated a recombinant SV that carries the wild-type IB gene (SV-IB wt), or a more stable mutant form of IB (SV-IB M), each containing three influenza virus HA epitope tags. As a control, we inserted the HA-tagged IB wt in the reverse orientation into the SV vector. Infection of AT-3 cells with SV-IB wt or SV-IB M revealed the expression of HA-tagged IB 8 h after infection (Fig. 1, A and B). Using an anti-HA antibody, we detected two bands reflecting HA-IBs that likely are translated from different initiation sites within the HA-tagged region on the virus vector (Fig. 1 B). As expected, quantitative analysis of immunoblots using ECF and phosphorimaging showed 20% greater levels of HA-IB in extracts from SV-IB M–infected cells as compared with extracts from SV-IB wt-infected cells.

View larger version (56K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Inhibition of SV-induced NF-B activity in AT-3 cells by heterologous expression of the inhibitory subunit of NF-B, IB in a SV vector. (A–C) Cytoplasmic extracts were prepared from AT-3 cells infected with SV-IB wt, SV-IB M, or SV-IB R at the time points indicated. A shows a Western blot analysis against IB. HA-IB corresponds to the heterologous HA-tagged human IB ; IB corresponds to the endogenous IB ; endogenous nonphosphorylated IB and nonspecific bands are denoted by an asterisk and N.S., respectively. (B) The blot shown in A was stripped, and anti-HA immunoreactive proteins are shown. C shows the Western blot analysis against the sindbis virus structural proteins. The upper arrow points to the viral envelope glycoproteins E1 and E2; the lower arrow points to the viral capsid protein. (D) EMSA performed with 6–8 µg of nuclear extracts corresponding to cytoplasmic extracts used in A–C using a 32P-labeled oligonucleotide with a consensus NF-B sequence from the MHC class I promoter. Upper arrow points to the predominant complex induced by SV, p50-p65 heterodimer; the lower arrow points to p50–p50 homodimers. The composition of the induced NF-B complexes were identified in a previous study (Lin et al., 1995).

To determine whether the expressed IBs are able to suppress SV-induced NF-B activity, we performed EMSAs on nuclear extracts from infected and mock-infected cells using a ³²P-labeled probe with a consensus NF-B binding site. As shown in Fig. 1 D, 8 h after infection, SV-IB R elicited a dramatic increase in two NF-B complexes, previously defined as p50–p65 and p50–p50 (Lin et al., 1995); SV-IB M completely suppressed p50–p65 activity and diminished p50–p50 activity; and SV-IB wt induced a level of p50–p65 activity intermediate between the SV-IB M and the SV-IB R. The differences in NF-B activity among recombinant SV-IBs was not due to their different replication rates in AT-3 cells, because levels of SV structural proteins (envelope glycoproteins, E1/E2, and capsid proteins) were similar in cells infected with each recombinant virus (Fig. 1 C).

Complete Suppression of SV-induced NF-B Activity Does Not Inhibit SV-induced Apoptosis in AT-3 Cells
We demonstrated that SV-induced NF-B activity could be suppressed using a recombinant SV containing a wt or mutant form of IB . To determine the effects of suppressing SV-induced NF-B activity on apoptosis, we measured viability of cells infected with the different recombinant viruses at several time points after infection. As shown in Fig. 2, we found that SV-IB wt, SV-IB M, and SV-IB R triggered cell death with similar kinetics in AT-3 cells. Similar results were observed in BHK cells (data not shown). These results suggest that SV-induced NF-B activity is not required for SV-induced apoptosis. However, in a previous study we established that NF-B is required for SV-induced death by pretreating AT-3 cells with NF-B–specific transcription factor decoys that competitively inhibit binding of NF-B to its target DNA sites. To reconcile these apparently conflicting observations, we hypothesized that NF-B activity before infection is necessary for SV-induced apoptosis; that is, steady-state levels of NF-B may regulate expression of latent death genes before SV infection.

View larger version (9K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Cell viability of AT-3 cells infected with SV-IB wt, SV-IB M, and SV-IB R. Percent viability was determined 24 and 48 h after infection by the alamar blue assay. Results are expressed as the mean ± SEM for experiments performed in triplicate (P > 0.05). Error bars that did not show up are hidden by the symbols.

Stable Overexpression of IB M in AT-3 Cells Delays SV-induced Apoptosis

View larger version (81K): [in this window] [in a new window] [Download PPT slide]   Figure 3 The effect of stable overexpression of IB M on SV-induced apoptosis in AT-3 cells. (A) Western blot analysis demonstrating expression of HA-tagged IB M in two pools of AT-3 IB Zeo cell clones, but not in the corresponding AT-3 cells containing the zeocin resistance gene alone. (B) EMSA was performed using nuclear extracts obtained in parallel from SV-infected AT-3 Zeo or AT-3 IB Zeo cells O, 4, and 6 h after infection. The upper arrow points to the p50–p65 complex, and the lower arrow points to p50–p50 homodimers. (C) Cell viability of AT-3 Zeo and AT-3 IKB Zeo cells 40 h after SV infection. Viability was determined by LDH assay as described in Materials and Methods. and is expressed as mean ± SEM for three separate experiments (P < 0.005). (D) Basal level of NF-B transcriptional activity was nearly completely suppressed in AT-3 IB Zeo cells compared with AT-3 Zeo cells. Basal level of NF-B activity was determined by B luciferase reporter system (P < 0.005).

Short-term Treatment of AT-3 Cells with N-acetyl-L-cysteine Combined with Infection of AT-3 Cells with SV-IB M, but not SV-IB R, Prevents Cell Death
We next used a different approach to confirm that inhibition of NF-B activity must be initiated in advance of the apoptotic stimulus to prevent SV-induced death. In previous studies, we demonstrated that NAC at 30 mM prevents SV-induced apoptosis without interfering with viral replication (Lin et al., 1995). Therefore, we infected AT-3 cells with recombinant SV-IBs in the presence of NAC. In this way, we could suppress activation of apoptosis induced by SV, but allow the recombinant SV to replicate and concomitantly express the exogenous HA–tagged IB M. As expected, nearly complete survival was maintained in SV-IB M and SV-IB R–infected cells in the presence of 30 mM NAC (Fig. 4 A), and expression of HA-tagged IB M in the SV-IB M–infected cells, but not the SV-IB R–infected cells, was verified by immunoblotting (data not shown). After 19 h, the NAC was removed. The cells infected with SV-IB M were significantly protected from cell death as compared with cells infected with SV-IB R 24 and 48 h after NAC withdrawal (Fig. 4 A). AT-3 cells that have been treated with NAC for 19 h appear to have no defects in NF-B activation, because 4 h after NAC withdrawal, cells infected with SV-IB R, but not the SV-IB M, elicited increased nuclear NF-B activity (Fig. 4 B).

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Short-term treatment of AT-3 cells with N-acetyl-L-cysteine (NAC) combined with infection with SV-IKB M, but not SV-IKB R, prevents cell death. (A) 2.5 x 103 cells/well in 96-well plates were infected with SV-IB M or SV-IB R, and were treated with 30 mM NAC for 19 h. The cells were washed twice with PBS, and fresh media without NAC was added. Cell viability was determined by the alamar blue assay 0, 24, and 48 h after NAC withdrawal. Results are expressed as the mean ± SEM for three experiments (P < 0.005) 24 and 48 hours after NAC withdrawal. (B) EMSAs were performed on nuclear extracts from SV-IB M and SV-IB R–infected cells 4 h after NAC withdrawal using 6–8 µg of protein and radiolabeled NF-B or AP-1 probes. The quality of the nuclear exatracts from the treated and infected cells was confirmed by analysis of AP-1 DNA activity, indicating that NAC does not interfere with global nuclear protein activity. The arrow points to the NF-B p50–p65 complex; the lower band is the NF-B p50–p50 complex.

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Cell viability of wt, p65 knockout, and p50 knockout embryo fibroblasts. (A) Viability of wt 3T3 cells infected with SV-IB wt, SV-IB M, and SV-IB R 24 h after infection (P > 0.05). (B) Viability of wt, p65–/–, and p50–/– 3T3 cells and EFs infected with wt SV 24 h after infection. 3T3 refers to immortalized fibroblasts, while EFs refers to primary fibroblasts. Viability was determined by LDH assay as described in Materials and Methods and normalized to identical cell densities among the three cell types. Results are expressed as mean ± SEM for 3–5 experiments (P < 0.05).

The Proapoptotic and Antiapoptotic Roles of NF-B are Determined by the Death Stimulus
Our observations that fibroblasts from p65^–/– mice are more resistant to SV–induced apoptosis are in contrast to previous observations that TNF –induced apoptosis is potentiated in fibroblasts from p65^–/– mice (Beg and Baltimore, 1996). These results suggest that the proapoptotic or antiapoptotic roles of NF-B are determined by the death stimulus, and are not necessarily dependent on the cell type. To examine this possibility further, we compared viabilities in populations of AT-3 Zeo and AT-3 IB M clones in response to a broad range of cytotoxic stimuli, including hydrogen peroxide (H₂O₂₎, TNF , the general protein kinase inhibitor staurosporine (STS), and serum deprivation. Similar to SV infection, we found that cell death induced by 100 µM (not shown) or 500 µM peroxide was delayed in two populations of IB M overexpressing cell clones as compared with control cells (Fig. 6 A); thus, in addition to SV infection, NF-B also appears to exhibit prodeath activity after peroxide treatment. In contrast (and in agreement with observations from others; Liu et al., 1996; Beg and Baltimore, 1996; Wang et al., 1996; van Antwerp et al., 1996), exposure of AT3-IB M cells to TNF (10 ng/ml) or staurosporine (STS at 100 nM or 2 µM) results in significantly greater levels of cell death than AT3-Zeo cells exposed to each of these stimuli (Fig. 6, B and C). Finally, AT-3 Zeo or AT-3 IB cells died at similar rates (P > 0.1) in response to 48 h of serum deprivation (Table I). These observations support the notion that the death stimulus is critically important in determining whether NF-B regulates prodeath, antideath proteins, or is an innocent bystander.

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Figure 6 The effect of overexpression of IB M on H2O2-, TNF -, and STS-induced death in AT-3 cells. Cell viability was determined by LDH assay as described in Materials and Methods, and results are expressed as mean ± SEM for three separate experiments. AT-3 Zeo or AT-3 IB Zeo cells exposed to: (A) 500 µM peroxide for 4 h (P < 0.005), (B) TNF- (10 ng/ml) for 24 h (P < 0.005), and (C) 100 nM or 2 µM STS for 24 or 48 h (P < 0.005).

View this table: [in this window] [in a new window]   Table I The Role of NF-B in Regulating Apoptosis in AT-3 Cells Depends on the Death Stimulus

	Discussion

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View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Proposed models by which NF-B regulates SV-induced apoptosis. (A) SV induces degradation of IB, allowing translocation of an NF-B heterodimer from the cytoplasm to the nucleus. NF-B activates transcription of one or more unknown death genes required for cell death. (B) Before infection, steady state NF-B activity regulates expression of an inactive form of a death protein that is posttranscriptionally or posttranslationally activated by SV, leading to apoptosis. In this scheme, SV-induced NF-B activity is not involved in regulating SV-induced apoptosis (dashed line).

How can the proapoptotic role of NF-B in the setting of SV infection be reconciled with the established antiapoptotic role of NF-B in response to other apoptotic stimuli? The stimulus, the cell type, and the subunit of NF-B activated have all been proposed as critical factors that determine whether this transcription factor promotes or suppresses apoptosis. We provide evidence suggesting that the stimulus may be the main factor in determining NF-B's ability to regulate divergent biological outcomes. First, overexpression of IB M in AT-3 cells protects from SV and H₂0₂-induced cell death, but potentiates TNF- and staurosporine-induced cell death, indicating that suppression of NF-B activity can be proapoptotic or antiapoptotic in the same cell type, depending on the stimulus. Second, fibroblasts from p65^–/–mice, but not p50^–/– mice, are resistant to SV-induced death, but more sensitive to TNF-–induced death. These observations show that the deleted subunit of NF-B is required for specific target gene activation leading to either a pro- or antiapoptotic response, but is not a necessary determinant in the proapoptotic or antiapoptotic actions of NF-B. Finally, our observation that serum deprivation–induced death occurs with similar kinetics in AT-3 Zeo and AT-3 IB Zeo cells suggests that NF-B is not part of this common pathway of apoptotic death, and that other stimulus-specific pathways may need to be simultaneously activated to determine NF-B's role in determining cell survival or death.

Our results are congruent with the emerging concept of private cell death pathways (Smith and Osborne, 1997). This notion acknowledges the existence of a common effector phase to apoptotic cell death, but states that within a given cell, many stimuli are capable of inducing apoptosis, and that each stimulus may do so by inducing a unique set of genes. These genes in turn may positively or negatively regulate activation of the common effector pathway. Heretofore, the best-studied examples of stimulus-specific cell death pathways have been in lymphocytes, where ionizing radiation (Lowe et al., 1993), glucocorticoids (Liu et al., 1994), and T cell activation (Woronicz et al., 1994) each activate unique transcription factor responses that converge on a common final effector pathway to apoptosis. Our studies carry this concept a step further, and suggest that a single transcription factor, NF-B, can mediate activation or suppression of cell death signals in the same cell type depending on the stimulus (Fig. 6; Table I). Furthermore, we identify that timing of NF-B activation is another important variable in determining whether this transcription factor regulates expression of prodeath proteins, or is an innocent bystander (Figs. 2, 3 C, and 5). The demonstration herein that steady-state NF-B activity is required to promote SV-induced cell death in AT-3 prostate carcinoma cells and 3T3 fibroblasts will focus future studies aimed at defining one or more NF-B–regulated genes required for SV-induced apoptosis.

Accumulating evidence indicates that apoptosis results from activation of a constitutively expressed suicide program that is conserved in evolution from nematodes to humans (Steller, 1995; Martin and Green, 1995). Interestingly, in prokaryotes such as Escherichia coli, a protease whose specific substrate is the translational elongation factor EF-Tu, is constitutively expressed. During infection with bacteria phage, this protease is activated and cleaves EF-Tu, leading to death of the cells (Snyder, 1995; Jacobson et al., 1997). Our findings suggest a parallel example in mammalian cells where SV infection posttranscriptionally or posttranslationally activates a constitutively expressed suicide program that is regulated in part, by NF-B before infection.

	Acknowledgments

 
We would like to thank Dr. Diane Griffin for helpful comments, and Dr. Brian Seed for providing the NF-B luciferase reporter construct. This work was supported by grants from the National Institutes of Health (NINDS R29 NS34943 and KO8 NS01951 R.R. Ratan).

Submitted: 26 January 1998

Revised: 22 April 1998

1. Abbreviations in this paper: EMSA, electrophoretic mobility shift assay; HA, hemagglutinin; M, mutant; NAC, N-acetylcysteine; R, reverse; SV, Sindbis virus; STS, staurosporine; wt, wild-type.

Address all correspondence to Rajiv R. Ratan, M.D., Ph.D., Neurology Laboratories at Beth Israel Deaconess Medical Center, Harvard Institutes of Medicine, Rm. 857; 77 Avenue Louis Pasteur, Boston, MA 02115.

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