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Molecular and Cellular Biology, September 2000, p. 6638-6645, Vol. 20, No. 18
0270-7306/00/$04.00+0
The Death Domain Kinase RIP Is Essential for TRAIL
(Apo2L)-Induced Activation of I
B Kinase and c-Jun
N-Terminal Kinase
Yong
Lin,1
Anne
Devin,1
Amy
Cook,1
Maccon M.
Keane,2,
Michelle
Kelliher,3
Stanley
Lipkowitz,2 and
Zheng-gang
Liu1,*
Department of Cell and Cancer
Biology1 and Department of
Genetics,2 Medicine Branch, Division of
Clinical Sciences, National Cancer Institute, National Institutes of
Health, Bethesda, Maryland 20892, and University of
Massachusetts Medical Center, Worcester, Massachusetts
016053
Received 13 March 2000/Returned for modification 17 April
2000/Accepted 16 June 2000
 |
ABSTRACT |
Tumor necrosis factor (TNF)-related apoptosis-inducing ligand
(TRAIL) (Apo2 ligand [Apo2L]) is a member of the TNF superfamily and
has been shown to have selective antitumor activity. Although it is
known that TRAIL (Apo2L) induces apoptosis and activates NF-
B and
Jun N-terminal kinase (JNK) through receptors such as TRAIL-R1 (DR4)
and TRAIL-R2 (DR5), the components of its signaling cascade have not
been well defined. In this report, we demonstrated that the death
domain kinase RIP is essential for TRAIL-induced IB kinase (IKK) and
JNK activation. We found that ectopic expression of the dominant
negative mutant RIP, RIP(559-671), blocks TRAIL-induced IKK and JNK
activation. In the RIP null fibroblasts, TRAIL failed to activate IKK
and only partially activated JNK. The endogenous RIP protein was
detected by immunoprecipitation in the TRAIL-R1 complex after TRAIL
treatment. More importantly, we found that RIP is not involved in
TRAIL-induced apoptosis. In addition, we also demonstrated that the TNF
receptor-associated factor 2 (TRAF2) plays little role in TRAIL-induced
IKK activation although it is required for TRAIL-mediated JNK
activation. These results indicated that the death domain kinase RIP, a
key factor in TNF signaling, also plays a pivotal role in TRAIL-induced
IKK and JNK activation.
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INTRODUCTION |
Tumor necrosis factor (TNF)-related
apoptosis-inducing ligand (TRAIL) (Apo2 ligand [Apo2L]) is a member
of the TNF superfamily, which includes TNF, FasL, lymphotoxin, CD27L,
OX40, CD30L, and CD40L (1, 30, 40). All members in this
superfamily are type II membrane proteins, and many of them are
involved in a variety of cellular processes, including cell
proliferation, differentiation, and apoptosis (42, 44).
Unlike other members, whose expression is transitorily regulated and
detected only in certain tissues, TRAIL (Apo2L) is constitutively
expressed in most types of tissues and cells (25, 34, 49).
It is believed that, like the active forms of TNF and FasL, the active
form of TRAIL is a trimer (15, 28). Five proteins, TRAIL-R1
(DR4), TRAIL-R2 (DR5), TRAIL-R3 (DcR1), TRAIL-R4 (DcR2), and
osteoprotegerin, have been identified as TRAIL receptors (9, 32,
33). Among these receptors, TRAIL-R1, TRAIL-R2, and TRAIL-R4 are
type I membrane proteins and belong to the TNF receptor (TNF-R)
superfamily (38, 47). Like TNF-R1 and Fas, which are known
as death receptors, TRAIL-R1 and TRAIL-R2 also contain a death domain
in their cytoplasmic region and are able to transduce a TRAIL-induced
death signal (5, 6, 33, 37). TRAIL-R4 only has a truncated
death domain and functions as a decoy receptor to block TRAIL-induced apoptosis (32). TRAIL-R3 is also a decoy receptor because it lacks a cytoplasmic region (38). Recently, it has been shown that osteoprotegerin, which was originally identified as a regulator of
bone density, is able to bind to TRAIL (9).
Upon binding to TRAIL-R1, TRAIL-R2, or TRAIL-R4, TRAIL can also
activate the transcriptional factor NF-B and c-Jun N-terminal kinase
(JNK) (5, 6, 29, 37). In response to many stimuli such as
TNF and interleukin-1 (IL-1), the activation of NF-B is mediated
through IB kinase (IKK) and JNK is activated through the
mitogen-activated protein kinase cascade, namely, JNKK1 (MKK4) and
MEKK1 (8, 18, 24, 26, 27, 35). The activation of JNK is a
major regulatory step to activate the transcription factor AP-1
(18). Inactive NF-B is located in the cytoplasm because
its interaction with the inhibitory proteins, IBs, masks its nuclear
translocation signal (3, 39). When IKK is activated, it
phosphorylates IBs. Then the phosphorylated IBs will be
polyubiquitinated and rapidly degraded by the proteasome
(3). The degradation of IBs leads to the release of
NF-B and allows NF-B to translocate into the nucleus and to
activate its target genes, some of which are the crucial mediators of
the NF-B antiapoptotic function (4, 23, 43, 48). It has
been found that NF-B activation also protects cells against
TRAIL-induced apoptosis (16, 17).
Although some effort has been made to elucidate the molecular mechanism
of TRAIL signaling, the components of different TRAIL signaling
pathways are still largely undefined, despite the fact that the
possible role of TRADD (TNF-R1-associated death domain protein), FADD
(Fas-associated death domain factor), TRAF2 (TNFR-associated factor 2),
or RIP (receptor-interacting protein) in TRAIL signaling has been
suggested (1). All of these four proteins are known to be
essential for TNF-R1 signaling: (i) TRADD serves as an adapter molecule
that recruits other proteins into the TNF-R1 complex (11-13); (ii) FADD is required for TNF-induced
apoptosis (50, 53); (iii) RIP is essential for
TNF-mediated NF-B activation (20, 41); and (iv) TRAF2
mediates TNF-induced JNK activation (21, 23, 31, 36, 51). In
this study, we investigated the role of RIP and TRAF2 in TRAIL
signaling, especially TRAIL-mediated IKK and JNK activation.
Using RIP
/ and TRAF2/
fibroblasts, we demonstrated that RIP is essential for TRAIL-induced IKK activation, and both RIP and TRAF2 are involved in TRAIL-mediated JNK activation. However, neither RIP nor TRAF2 is required for TRAIL-induced apoptosis.
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MATERIALS AND METHODS |
Reagents and plasmids.
Soluble recombinant human TRAIL was
purchased from Biomol. Glutathione S-transferase
(GST)-TRAIL was expressed and purified from Escherichia
coli as described elsewhere (19). Antibodies specific
to RIP, DR4, c-Myc, and JNK1 were purchased from Pharmingen. Anti-FADD
antibody was from Transduction Laboratories. Antibodies directed
against TRADD, IKK
, IKK
, IB, and hemagglutinin epitope (HA)
were from Santa Cruz Biotechnology. Anti-phospho-IB antibody was
from New England Biolabs. Anti-Flag antibody (M2) was from Sigma. The
mammalian expression plasmids for RIP, RIP(559-671), TRAF2,
TRAF2(87-501), CrmA, FADD, TRADD, DR4, HA-JNK1, and HA-IKK have
been previously described (12, 13, 23, 32, 52).
Cell culture and transfection.
HeLa, HEK293, and mouse
fibroblast cells were cultured in Dulbecco's modified Eagle's medium
supplemented with 10% calf serum, 2 mM glutamine, penicillin (100 U/ml), and streptomycin (100 µg/ml). Cells were transfected with
Lipofectamine (Gibco) as described previously (22).
Western blot analysis and coimmunoprecipitation.
After
treatment with different reagents as described in the figure legends,
cells were collected and lysed in M2 buffer (20 mM Tris [pH 7], 0.5%
NP-40, 250 mM NaCl, 3 mM EDTA, 3 mM EGTA, 2 mM dithiothreitol, 0.5 mM
phenylmethylsulfonyl fluoride, 20 mM -glycerol phosphate, 1 mM
sodium vanadate, 1 µg of leupeptin/ml). Fifty micrograms of the cell
lysate from each sample was fractionated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western
blotted. The proteins were visualized by enhanced chemiluminescence as
instructed by the manufacturer (Amersham) (22). For
immunoprecipitation assays of transfected proteins, HEK293 cells were
transiently cotransfected with different plasmids and then lysed in
lysis buffer (20 mM Tris-HCl [pH 7.5], 150 mM NaCl, 1% Triton X-100,
1 mM EDTA, 30 mM NaF, 2 mM sodium pyrophosphate, 10 µg of
aprotinin/ml, 10 µg of leupeptin/ml). The expression of each
transfected protein was verified by Western blotting. The
immunoprecipitation experiments were performed with anti-Flag antibody
(M2) and protein A-Sepharose beads by incubation at 4°C overnight.
The beads were washed three times with lysis buffer, and the bound
proteins were resolved by SDS-PAGE on a 10% gel. Detection was
accomplished by Western blot analysis (22). For immunoprecipitation assays of endogenous proteins, 5 × 107 HeLa cells were treated with TRAIL (1 µg/ml) for 30 min as indicated in the legend to Fig. 6. The cells were then lysed in
lysis buffer and precipitated with 2 µg of anti-DR4 antibody as
described above.
Kinase assays.
HeLa cells or mouse fibroblasts (5 × 105) were treated with TRAIL or GST-TRAIL, respectively, as
described in the figure legends. Cells were collected in 300 µl of M2
lysis buffer. IKK complex and JNK1 were immunoprecipitated with
anti-IKK and anti-JNK1 antibodies, respectively. IKK and JNK kinase
activities were determined by using 2 µg of GST-IB(1-54) and
GST-c-Jun(1-79), respectively, as substrates.
Transfected cells were collected in 300 µl of M2 lysis buffer 24 h after transfection as described elsewhere (23). HA-JNK1 and HA-IKK were immunoprecipitated with HA antibody, and their kinase activities were determined as described above.
| |
RESULTS |
TRAIL induces IKK and JNK activation in HeLa cells.
Upon
NF-B-inducing stimulation, IB is phosphorylated by IKK and
degraded in the proteasome. To investigate whether TRAIL induces IKK
activation, a time course of TRAIL treatment in HeLa cells was
conducted, and the levels of IB protein were detected at
different time points after treatment by Western blotting. We found
that the IB protein level began to decline after 45 min of TRAIL
treatment and started to recover by 120 min of treatment; the FADD
protein level, measured as a control, showed no significant change
(Fig. 1A). Then we tested whether
TRAIL-induced IB degradation is induced by IKK. To do this, we
treated HeLa cells with TRAIL for different times and measured the IKK
activity of each sample by in vitro kinase assay with
GST-IB(1-54) as the substrate (52). As shown in Fig.
1B, IKK activity started to increase after 30 min of treatment and
peaked at 45 min posttreatment. Although the kinetics of TRAIL-induced
IKK is slower than the kinetics of TNF treatment (8), TRAIL
potently activates IKK, suggesting that TRAIL induces IB degradation
through the IKK pathway. This conclusion is further supported by the
observation that IB is phosphorylated at Ser32 following TRAIL
treatment (Fig. 1C). The ability of TRAIL to induce JNK activation was
also measured in HeLa cells by in vitro kinase assay with
GST-c-Jun(1-79) as the substrate (23). Again, TRAIL
induced a slower but similar extent of JNK activation as TNF does in
HeLa cells (Fig. 1D). These results indicated that TRAIL, like TNF,
activated IKK and JNK in HeLa cells.
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FIG. 1.
Activation of IKK and JNK in HeLa cells by TRAIL. (A)
Time course of IB degradation in TRAIL-treated HeLa cells. Cells
were treated with TRAIL (1 µg/ml) and incubated for the indicated
time periods. IB and FADD were detected by Western blot analysis.
(B) Time course of IKK activation in TRAIL-treated HeLa cells. Cells
were treated with TRAIL and collected in lysis buffer. Then IKK
expression was detected by Western blotting (bottom), and its activity
was measured by an IKK assay (top). (C) HeLa cells were treated with
TRAIL (1 µg/ml) and incubated for the indicated time periods.
IB and phospho-IB were detected by Western blot analysis.
(D) Time course of JNK activation in TRAIL-treated HeLa cells. Cells
were treated as indicated; then JNK1 expression or activity from each
sample was measured by Western blotting (bottom) or kinase assay (top),
respectively.
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|
The dominant negative mutant of RIP, RIP(559-671), blocked
TRAIL-induced IKK and JNK activation.
RIP and TRAF2 are essential
for TNF-induced activation of NF-B and JNK (20-23, 31, 36, 41,
51). It has been suggested that TRAF2 plays a similar role in
TRAIL-R1- and TRAIL-R2-mediated NF-B and JNK activation
(14). To investigate whether TRAIL-induced IKK activation is
mediated by RIP, we tested the effect of the dominant negative mutant
of RIP, RIP(559-671), on TRAIL-induced IKK activation in HeLa cells.
The role of TRAF2 on TRAIL-induced IKK activation in HeLa cells was
also evaluated by overexpression of the dominant negative mutant of
TRAF2, TRAF2(87-501). HA-tagged IKK was cotransfected with the
RIP(559-671) or TRAF2(87-501) expression vector, and its kinase
activity was measured by in vitro kinase assay after
immunoprecipitation with the anti-HA antibody. In the case of
RIP(559-671), the expression vector for the cowpox virus protein CrmA,
a potent apoptosis inhibitor, was also included in order to inhibit
RIP(559-671)-induced apoptosis. As shown in Fig.
2A, the ectopic expression of
RIP(559-671) almost completely abolished TRAIL-induced IKK activation
(top panel, lane 3), while overexpression of TRAF2(87-501) only
partially inhibited IKK activation after TRAIL treatment (top panel,
lane 4). As controls, the CrmA, wild-type (wt) RIP, or wt TRAF2
expression vector was also used to cotransfect cells with HA-IKK.
The expression of CrmA, wt RIP, or TRAF2 has no effect on TRAIL-induced
IKK activation (data not shown). The expression level of HA-IKK,
RIP(559-671), or Flag-TRAF2(87-501) was detected with anti-HA,
anti-RIP, or anti-Flag antibody, respectively. To understand the roles
of RIP and TRAF2 in TRAIL-mediated JNK activation, cotransfection
experiments were performed with HA-JNK1 and RIP(559-671) or
TRAF2(87-501) as described above. HA-JNK1 was immunoprecipitated with
the anti-HA antibody, and its kinase activity was determined by in
vitro kinase assay. In the presence of either RIP(559-671) or
TRAF2(87-501), as detected by Western blotting with anti-RIP or
anti-Flag antibody (Fig. 2B), TRAIL-induced JNK activation was
completely blocked (Fig. 2B, top). The expression level of HA-JNK was
measured by Western blotting with the anti-HA antibody. The CrmA, wt
RIP, and wt TRAF2 expression vectors were used as controls. The
presence of CrmA, wt RIP, or wt TRAF2 has no effect on TRAIL-induced
JNK activation (data not shown). These results indicated that ectopic expression of the dominant negative mutant RIP potently disrupted TRAIL-induced activation of both IKK and JNK, implying that RIP may
play an essential role in both IKK and JNK activation by TRAIL treatment. However, because overexpression of dominant negative mutant
TRAF2 had more profound, disruptive effect on TRAIL-induced JNK
activation than on IKK activation, the function of TRAF2 may be more
critical for JNK activation than for IKK activation by TRAIL.
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FIG. 2.
Effects of dominant negative mutants of RIP and TRAF2 on
TRAIL-induced IKK and JNK activation in HeLa cells. (A) HeLa cells were
transfected with 0.5 µg of HA-IKK (lanes 1 and 2) or cotransfected
with 0.5 µg of HA-IKK, 0.2 µg of CrmA, and 1 µg of
RIP(559-671) (lane 3) or TRAF2(87-501) (lane 4). Twenty-four hours
posttransfection, the cells were treated with TRAIL (1 µg/ml) for 30 min (lanes 2 to 4). IKK activity was detected by kinase assay. The
expression of each introduced factor is shown. (B) HeLa cells were
transfected with 0.5 µg of HA-JNK1 (lanes 1 and 2) or cotransfected
with 0.5 µg of HA-JNK1, 0.2 µg of CrmA, and 1 µg of RIP(559-671)
(lane 3) or TRAF2(87-501) (lane 4). Twenty-four hours
posttransfection, the cells were treated with TRAIL (1 µg/ml) for 30 min (lanes 2 to 4). Cells were collected, and the expression of
HA-JNK1, RIP(559-671) and TRAF2(87-501) was detected by Western
blotting. The JNK assay was performed as described in Materials and
Methods.
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|
TRAIL failed to induce IKK activation in RIP/
fibroblasts, while TRAIL-induced JNK activation was impaired in both
RIP/ and TRAF2/ cells.
To further
evaluate the roles of RIP and TRAF2 in TRAIL-induced NF-B
activation, we investigated IB degradation by Western blotting and
IKK activation by in vitro kinase assay in response to TRAIL treatment
in RIP/ and TRAF2/ mouse fibroblasts.
The wt fibroblasts were used as controls. In these experiments,
GST-TRAIL, instead of TRAIL, was used to treat cells, as it exerted
better activity in mouse fibroblasts (data not shown). In the wt cells,
IB degradation was detectable by 15 min after treatment, and most
degradation was observed by 30 min after TRAIL treatment (Fig.
3A, top). The IB level returned to
its normal level by 75 min after TRAIL treatment. In
TRAF2/ cells, IB degradation showed similar
kinetics (Fig. 3A, middle). However, there was no detectable
degradation of the IB protein in the RIP/ cells
after TRAIL treatment (Fig. 3A, bottom). The activation of IKK in these
cells was also determined. TRAIL treatment efficiently activated IKK in
both wt and TRAF2/ cells (Fig. 3B, top). In contrast,
TRAIL-induced IKK activation was barely detected in
RIP/ cells. Since comparable expression levels of
IKK, IKK, and one of the major TRAIL receptors, TRAIL-R1, were
detected in these three types of cells (Fig. 3B [middle panels] and
data not shown), it is unlikely that the decrease of IKK activation in
RIP/ cells resulted from the altered expression of IKK
or TRAIL receptor. The protein levels of RIP and TRAF2 were also
measured by Western blotting (Fig. 3B, bottom). Furthermore, the
absence of the IKK activation in RIP/ cells is TRAIL
specific, because these RIP/ cells displayed normal
IL-1-induced IKK activation as the wt and TRAF2/ cells
did (Fig. 3C). Taken together, these results further supported the
observation from the transient transfection experiments: RIP, not
TRAF2, plays an essential role in TRAIL-induced IKK activation.
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FIG. 3.
RIP/ cells are insensitive to
TRAIL-induced IB degradation and IKK activation. (A) Wild-type,
RIP/, and TRAF2/ mouse fibroblasts were
treated with GST-TRAIL (10 µg/ml) for the indicated time periods.
IB was detected by Western blot analysis. (B) Wild-type,
RIP/, and TRAF2/ mouse fibroblasts were
treated with GST-TRAIL (10 µg/ml) for 30 min. IKK, DR4, RIP, and
TRAF2 were detected by Western blot analysis. The IKK complex was
precipitated, and a kinase assay was performed as described in
Materials and Methods. Nontreated cells served as controls. (C)
Wild-type, RIP/, and TRAF2/ mouse
fibroblasts were treated with IL1 (4 ng/ml) for 10 min and subjected to
an IKK assay.
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|
Similarly, we used RIP
/ and TRAF2
/
fibroblasts to further determine the functions of RIP and TRAF2 in
TRAIL-induced JNK activation.
TRAIL activated JNK efficiently in wt
fibroblasts, but only marginally
in both RIP
/ and
TRAF2
/ cells (Fig.
4A,
top). Similar levels of JNK1 expression in these
cells were detected
(Fig.
4A, bottom). These results suggested
that both RIP and TRAF2 are
required for transducing the TRAIL
signal to fully activate JNK. The
defectiveness of JNK activation
in RIP
/ and
TRAF2
/ cells was specific to TRAIL treatment because
those RIP
/ and TRAF2
/ cells responded
to IL-1 and UV treatment as efficiently as the
wt cells did in terms of
JNK activation (Fig.
4B and data not
shown).
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FIG. 4.
TRAIL-induced JNK activation was impaired in both
RIP/ and TRAF2/ cells. (A) Wild-type,
RIP/, and TRAF2/ mouse fibroblasts were
treated with GST-TRAIL (10 µg/ml) for 30 min, and a JNK assay was
performed. JNK1 was detected by Western blot analysis as described in
Materials and Methods. Nontreated cells served as controls. (B)
Wild-type, RIP/, and TRAF2/ mouse
fibroblasts were treated with IL-1 (4 ng/ml) for 10 min, and a JNK
assay was performed. Nontreated cells served as controls.
|
|
To rule out the possibility that some other defects in the signaling
pathway of TRAIL-induced IKK or JNK activation are present
in
RIP
/ or TRAF2
/ cells, we tested whether
TRAIL-induced IKK or JNK activation
could be reconstituted in those
cells. To examine the reconstitution
of TRAIL-induced IKK activation,
the expression vector for either
Myc-RIP or Flag-TRAF2 was
cotransfected with HA-IKK
into RIP
/ or
TRAF2
/ cells, respectively. Following treatment with
GST-TRAIL, the
transfected HA-IKK
was immunoprecipitated for in
vitro kinase
assay. As shown in Fig.
5A,
RIP expression could restore the IKK
activation in response to TRAIL
treatment in RIP
/ cells. Since TRAIL-induced IKK
activation was normal in TRAF2
/ cells (Fig.
3B), the
expression of TRAF2 had little effect on
TRAIL-induced IKK activation
in TRAF2
/ cells. Similarly, we also ectopically
expressed Myc-RIP or Flag-TRAF2
with HA-JNK1 in RIP
/ or
TRAF2
/ cells, respectively, in order to measure the
reconstitution of
TRAIL-induced JNK activation. In these experiments,
HA-JNK1 was
immunoprecipitated for in vitro kinase assay. As shown in
Fig.
5B, the expression of RIP in RIP
/ cells or the
expression of TRAF2 in TRAF2
/ cells restored JNK
activation in response to TRAIL. These results
indicated that the
defects in TRAIL-induced IKK or JNK activation
in RIP
/
and TRAF2
/ cells are due to the absence of RIP or
TRAF2.
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FIG. 5.
Reconstitution of TRAIL-induced IKK and JNK activation
in RIP/ and TRAF2/ cells. (A)
Wild-type, RIP/, and TRAF2/ mouse
fibroblasts cells were cotransfected with HA-IKK and Myc-RIP or
Flag-TRAF2 expression plasmids as indicated. Twenty four hours after
transfection, cells were treated with GST-TRAIL (10 µg/ml) for 30 min
and subjected to an IKK assay. HA-IKK, Myc-RIP, and Flag-TRAF2 were
detected by Western blotting. Nontreated cells served as controls. (B)
Wild-type, RIP/, and TRAF2/ mouse
fibroblasts were cotransfected with HA-JNK1 and Myc-RIP or Flag-TRAF2
expression plasmids as indicated. Cells were treated with GST-TRAIL (10 µg/ml) for 30 min and analyzed by JNK assay. HA-JNK1, Myc-RIP, and
Flag-TRAF2 were detected by Western blotting. Nontreated cells served
as controls.
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RIP is a component of the TRAIL-R1 signaling complex.
It is
believed that as for TNF, TRAIL ligation initiates its receptors'
trimerization and that this aggregation of TRAIL receptors leads to the
recruitment of downstream effector molecules to the receptor signaling
complex (1, 15, 28). Since our data suggested that RIP is
essential in TRAIL-induced activation of both IKK and JNK, it might be
a component of the TRAIL receptor complex. To test this possibility, we
first investigated whether RIP interacts with TRAIL receptors by
ectopic expression of RIP and TRAIL-R1 in HEK293 cells. Because RIP is
recruited to the TNF-R1 complex through TRADD and it has been suggested
that FADD is involved in RIP-TRAIL-R1 interaction, we also studied the
interaction between RIP and TRAIL-R1 in the presence of TRADD, FADD, or
both. In each experiment, Flag-tagged TRAIL-R1 was immunoprecipitated with anti-Flag antibody and the immunoprecipitates were analyzed by
Western blotting with an anti-RIP antibody. As shown in Fig. 6A, although RIP and TRAIL-R1 were
expressed at similar levels in each transfection, RIP was not
coprecipitated with Flag-TRAIL-R1 (lane 2). Even in the presence of
FADD or TRADD, immunoprecipitation of Flag-TRAIL-R1 failed to pull down
RIP (lanes 3 and 4). However, RIP was efficiently coprecipitated with
Flag-TRAIL-R1 when both FADD and TRADD were coexpressed with TRAIL-R1
(lane 5). As a control, when TRAIL-R1 was not coexpressed with RIP,
FADD, and TRADD, RIP was not precipitated (lane 6). These results
suggested that RIP binds to TRAIL-R1 indirectly. To test whether
endogenous RIP is recruited to the TRAIL-R1 complex, we performed
coimmunoprecipitation experiments to analyze the TRAIL-R1 complex with
cell extracts derived from HeLa cells with or without TRAIL
treatment. In these experiments, endogenous TRAIL-R1 was
immunoprecipitated with anti-DR4 antibody, and the immunoprecipitates
were analyzed with different antibodies. As shown in Fig. 6B, while RIP
was not coprecipitated by anti-DR4 antibody from the nontreated cell
extract (lane 3), RIP was present in the TRAIL-R1 complex that was
immunoprecipitated from the cell extract with TRAIL treatment (lane 6).
The control antibody, anti-HA, failed to pull down RIP (lanes 2 and 5).
However, no TRADD and FADD were detected in the same TRAIL-R1 complex
when the same blot was probed with anti-TRADD and anti-FADD antibodies (data not shown). These results suggested that TRAIL treatment induces
the recruitment of RIP to the TRAIL-R1 complex. Although overexpression
of TRADD and FADD can help RIP bind to TRAIL-R1, both TRADD and FADD
are not in the TRAIL-R1 complex.
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FIG. 6.
RIP is present in the TRAIL-R1 complex. (A) HEK293 cells
were cotransfected with RIP (2.5 µg) and CrmA (1 µg) along with 2.5 µg of Flag-DR4, FADD, or TRADD as indicated. Cells were collected 24 hours after transfection. Expression of Flag-DR4, RIP, TRADD, and FADD
was determined by Western blotting (bottom). Coimmunoprecipitation
(Co-IP) experiments were performed with anti-Flag antibody (M2), and
coprecipitated RIP proteins were detected by Western blotting (top).
(B) HeLa cells (2 × 107) were treated with TRAIL (1 µg/ml) for 20 min or not treated. Immunoprecipitation experiments
were performed with anti-DR4 (lanes 3 and 6) or anti-HA (lanes 2 and 5)
antibody, and the coprecipitated RIP protein was detected by Western
blotting.
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|
Neither RIP nor TRAF2 is required for TRAIL-induced apoptosis.
TRAIL is a potent inducer of apoptosis, but the molecular mechanism of
TRAIL-induced apoptosis is still unclear (1). Since our
study suggested that RIP and TRAF2 are important components of the
TRAIL signaling pathway, we next investigated whether RIP and TRAF2 are
involved in TRAIL-induced apoptosis. Normally, fibroblasts do not die
upon TRAIL treatment, but they can be rendered sensitive to TRAIL in
combination with cycloheximide (CHX) treatment. Therefore, to
induce apoptosis, the wt, RIP/, and
TRAF2/ cells were treated with both GST-TRAIL and
CHX. Cells were collected at 0, 2, 4, 6, 8, and 24 h after
treatment, and the percentage of apoptosis in each type of cells was
determined by trypan blue exclusion staining. As shown in Fig.
7, the absence of RIP or TRAF2 had no
effect on TRAIL-induced apoptosis since both RIP/ and
TRAF2/ cells died to the same extent as the wt cells.
These results suggested that both RIP and TRAF2 are not required for
TRAIL-induced apoptosis.
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FIG. 7.
TRAIL-induced apoptotic cell death in wt,
RIP/, and TRAF2/ cells. Cells were
treated with GST-TRAIL (10 µg/ml) and CHX (10 µg/ml) for the
indicated periods of time. Dead cells were determined by trypan blue
staining. The results shown are averages of three independent
experiments.
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DISCUSSION |
Because TRAIL selectively induces apoptosis in tumor or
transformed cells but not in normal cells, it has shown great potential to be a valuable tumor therapeutic agent (2, 10, 46). Like other members of the TNF superfamily, TRAIL has other biological functions such as activating transcription factor NF-B and JNKs (14, 16, 17, 29, 37). Although much effort has been made to
investigate the biological functions of TRAIL since it was discovered,
the molecular mechanism of TRAIL signaling is still largely unknown.
Recently, it was suggested that TRAF2, an important effector of TNF
signaling, was involved in both NF-B and JNK activation induced by
overexpression of TRAIL receptors (14). In our study, we
reported that another critical effector of TNF signaling, RIP, plays a
critical role in TRAIL-induced activation of both IKK and JNK. We also
found that while overexpression of the dominant negative mutant TRAF2
blocked TRAIL-induced IKK and JNK activation, the absence of TRAF2
affected TRAIL-induced JNK activation but had little effect on IKK
activation. In addition, we also demonstrated that neither RIP nor
TRAF2 was required for TRAIL-induced apoptosis.
The death domain kinase RIP is an essential effector for TNF-induced
NF-B activation (20, 41). It has been suggested that RIP
plays a similar role in DR3/Apo3-mediated NF-B activation (1). Here we provided evidence that RIP is also essential in TRAIL-induced NF-B activation. The dominant negative mutant of RIP
efficiently blocked TRAIL-induced IKK activation. In
RIP/ cell lines, no IKK activity was detected following
TRAIL treatment. Furthermore, we found that RIP was present in the
TRAIL-R1 complex, whose formation is TRAIL dependent. However, because
RIP does not directly interact with TRAIL-R1 (Fig. 6A), it seems that
the recruitment of RIP requires additional adapter molecules. In
previous overexpression experiments, it was shown that the presence of TRADD and FADD resulted in the interaction of TRAIL-R1 and RIP (5). Our results have confirmed this observation (Fig. 6A). But since TRADD and FADD were not found in the TRAIL-R1 complex (Fig.
6B), they may not be the molecules that mediate the endogenous TRAIL-R1-RIP interaction. Consistent with this possibility, it has
been shown that FADD is not required for TRAIL-R1-mediated apoptosis
(25). Therefore, it is possible that the recruitment of RIP
to TRAIL receptors is mediated by other death domain-containing factors.
Previous studies involving overexpression of the dominant negative
mutant RIP had shown that RIP was involved in TNF-induced JNK
activation (23). However, a study using RIP knockout mice showed that RIP had little effect on TNF-induced JNK activation (20). In this study, however, we found that RIP was required for TRAIL-induced JNK activation. Overexpression of the dominant negative mutant RIP completely abolished TRAIL-induced JNK activation (Fig. 2). In addition, TRAIL-induced JNK activation was greatly decreased in RIP/ cells (Fig. 4). These data suggested
that RIP is involved in IKK and JNK activation by TRAIL treatment.
Therefore, RIP is a critical effector in TRAIL signaling.
TRAF2 was initially identified as a component of the TNF-R2 complex and
was also found in the TNF-R1 signaling complex (23, 31).
Previous studies involving overexpression of TRAF2 and its dominant
negative mutant had shown that TRAF2 played a critical role in
TNF-induced NF-B and JNK activation. However, the aforementioned study with a genetic approach reported that removal of TRAF2 caused the
diminishment of TNF-induced JNK activation and had only a minor effect
on TNF-induced NF-B activation (51). In this study, we
found that TRAF2 had a similar effect on TRAIL signaling: the absence
of TRAF2 severely affected TRAIL-induced JNK activation but had no
detectable effect on IKK activation (Fig. 3 and 4). But in the
overexpression experiments, we found that TRAIL-induced activation of
both IKK and JNK was blocked by the dominant negative mutant of TRAF2
(Fig. 2). This observation is consistent with a recent report
(14). One possibility is that other TRAF proteins, such as
TRAF5, may replace the function of TRAF2 to mediate TRAIL-induced IKK
activation. Therefore, the effect of the absence of TRAF2 on
TRAIL-induced IKK activation might be minimized by the presence of
other TRAF proteins. However, when the dominant negative mutant of
TRAF2 is overexpressed, it might also block the function of other TRAF
proteins; as a result, overexpression of the dominant negative mutant
of TRAF2 inhibits TRAIL-induced IKK activation. Further studies are
necessary to elucidate the role of TRAF proteins in TRAIL-induced IKK activation.
It has been reported that FADD is dispensable for TRAIL-induced
apoptosis although it is essential for TNF- and Fas-mediated cell death
(25, 50, 53). But because overexpression of dominant negative FADD efficiently blocked TRAIL-induced apoptosis
(45), it is possible that a FADD-like death factor mediates
TRAIL-induced cell death. In this study, we demonstrated that neither
RIP nor TRAF2 is required for TRAIL-induced apoptosis (Fig. 7).
Although JNK activation is essential for cells to undergo apoptosis in some circumstances, it is unlikely that JNK activation is involved in
TRAIL-induced apoptosis since TRAF2/ cells died to the
same extent as wt fibroblasts. On the other hand, because NF-B
activation provides an antiapoptotic effect (4, 23, 43, 48),
RIP-mediated NF-B activation following TRAIL treatment may protect
cells against TRAIL-induced apoptosis. Unfortunately, because
RIP/ fibroblasts are insensitive to TRAIL treatment and
CHX is necessary to induce death of RIP/ cells, we
failed to evaluate the antiapoptotic effect of NF-B activation in
TRAIL-induced apoptosis with those fibroblasts. However, we found in a
previous study that RIP was cleaved by caspase-8 in Fas-, TNF-, and
TRAIL-induced apoptosis (22). Importantly, the cleavage of
RIP abolished its ability to efficiently activate NF-B. Therefore,
NF-B activation may also be antiapoptotic in response to TRAIL
treatment. This possibility is further supported by the observation
that inhibition of NF-B activation sensitized several types of tumor
cells to TRAIL treatment (16, 17).
Taken together, the results of our study shed some light on the
molecular mechanisms of TRAIL signaling. We demonstrated that both RIP
and TRAF2 are important effectors of TRAIL signaling. In addition,
neither RIP nor TRAF2 is required for TRAIL-induced apoptosis. Because
TRAIL has been pursued as a potential cancer therapy, knowledge of
TRAIL signaling will accelerate this process and help in developing new
strategies for improving its therapeutic value.
| |
ACKNOWLEDGMENTS |
We thank W. C. Yeh and T. W. Mak for
TRAF2/ fibroblasts and C. Vincenz for DR4 plasmid. We
also thank J. Lewis for assistance in manuscript preparation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Medicine Branch,
NCI, NIH, Bldg. 10, Rm. 6N105, 9000 Rockville Pike, Bethesda, MD 20892. Phone: (301) 435-6351. Fax: (301) 402-1997. E-mail:
zgliu{at}helix.nih.gov.
Present address: Department of Medical Oncology, University
Hospital of Galway, Galway, Republic of Ireland.
| |
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Abstract
Introduction
