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J Biol Chem, Vol. 274, Issue 43, 30882-30886, October 22, 1999
From the Engagement of the tumor necrosis factor- The tumor necrosis factor
(TNF)1- The ability of both TNFR1 and TNFR2 to transduce signals is dependent
upon the interaction of their cytoplasmic tails with intracellular
proteins (see Ref. 9 for review). The intracellular domain of TNFR1, in
contrast to TNFR2, contains a region called the "death domain,"
which binds adapter proteins such as TRADD (TNFR-associated death
domain protein) (10). TRADD binds two additional
transducers, TRAF2 (TNFR-associated
factor-2) and receptor-interacting protein
(11). These proteins, in turn, induce the kinase cascades ultimately
resulting in the activation of the transcription factor NF- Induction of gene expression is an important consequence of TNFR1
and/or TNFR2 engagement and is essential for many of the biological
responses of TNF- Signaling through TNFR1 leads to gene induction via activation of the
I Here, we show that selective signaling through TNFR1 results in the
induction of TNF- Plasmids, Cell Culture, and Transfections--
The
Murine L929 fibroblasts were cultured in Dulbecco's modified Eagle's
medium supplemented with 10% fetal calf serum, 12 mM HEPES, 2 mM glutamine, 50 µM
Electrophoretic Mobility Shift Assay--
L929 cells were
incubated for 2 h with or without 100 units/ml rhTNF- RNase Protection Assay--
RNA was prepared from L929 cells
stimulated with TNF- Immunoprecipitation and Western Blot Analysis--
Nuclear
extracts and whole cell extracts were prepared from L929 cells after a
15-min stimulation with 1000 units/ml rhTNF- Engagement of TNFR1 Induces TNF-
To identify the TNF- MADD, but Not TRADD, Activates TNF-
A truncated form of MADD containing the death domain, called 15TU, also
activates the JNK and ERK pathways (13). We tested whether the MADD
death domain was sufficient for activation of TNF- The TNF- ATF-2/Jun Proteins Constitutively Bind to the CRE in L929
Cells--
Given the functional importance of the CRE in
TNFR1-mediated TNF- TNFR1-mediated Phosphorylation of ATF-2 Is Dependent upon p38 MAP
Kinase--
Since ATF-2 becomes transcriptionally active upon
phosphorylation by p38 MAP kinase, we studied the role of p38 MAP
kinase activity in TNFR1-stimulated TNF-
To correlate the phosphorylation status of ATF-2 with the inhibitory
effect of SB203580 upon TNF-
To demonstrate that TNFR1 engagement resulted in an increase in p38 MAP
kinase activity, we prepared whole cell extracts of L929 cells
stimulated with rhTNF- Signaling through TNFR1 leads to at least three distinct effector
functions, including MAP kinase activation, NF- Signaling through TNFR1 and its subsequent association with TRADD,
TRAF2, and NF Our data also suggest a role for MADD in TNFR1-mediated TNF- Mice deficient in TNFR1 or TNF- The study presented here has demonstrated the required and critical
roles of p38 MAP kinase and ATF-2 in TNF- We thank Drs. Dimitris Thanos, Roger Davis,
and Nancy Rice for the gift of reagents.
*
This work was supported by National Institutes of Health
Grant CA58735 and an American Heart Association Established
Investigator award (to A. E. G.) and by a grant from Stichting Fonds
Dr. Catharine van Tussenbroek (to B. M. N. B.).The costs of publication of this article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
Present address: Variagenics, 1 Kendall Square, Cambridge, MA 02139.
**
To whom correspondence should be addressed. Tel.: 617-278-3351;
Fax: 617-278-3454; E-mail: goldfeld@cbr.med.harvard.edu.
The abbreviations used are:
TNF, tumor necrosis
factor;
rhTNF-
Engagement of Tumor Necrosis Factor (TNF) Receptor 1 Leads to
ATF-2- and p38 Mitogen-activated Protein
Kinase-dependent TNF-
Gene Expression*
,
**
Center for Blood Research and the
Department of Medicine, Harvard Medical School, Boston,
Massachusetts 02115 and the § Small Molecule Drug Discovery
Group, Genetics Institute, Cambridge, Massachusetts 02139
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
(TNF-) receptors by the TNF- ligand results in the rapid
induction of TNF- gene expression. The study presented here shows
that autoregulation of TNF- gene transcription by selective
signaling through tumor necrosis factor receptor 1 (TNFR1) requires p38
mitogen-activated protein (MAP) kinase activity and the binding of the
transcription factors ATF-2 and Jun to the TNF- cAMP-response
element (CRE) promoter element. Consistent with these findings, TNFR1
engagement results in increased p38 MAP kinase activity and
p38-dependent phosphorylation of ATF-2. Furthermore,
overexpression of MADD (MAP kinase-activating
death domain protein), an adapter protein that
binds to the death domain of TNFR1 and activates MAP kinase cascades,
results in CRE-dependent induction of TNF- gene
expression. Thus, the TNF- CRE site is the target of TNFR1
stimulation and mediates the autoregulation of TNF- gene transcription.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
gene encodes a
pleiotropic cytokine involved in multiple immunological responses (1). Furthermore, TNF- has been implicated in the pathogenesis of a
variety of infectious and autoimmune diseases where host production of
too much or too little TNF- is associated with variable patterns of
disease pathogenesis (1). The biological actions of TNF- are
initiated by its binding to a 55-kDa receptor (TNFR1) and/or to a
75-kDa receptor (TNFR2). Although these two receptors induce both
distinct and overlapping responses (see Ref. 2 for review), the
majority of TNF- effects, including the initiation of cell death
cascades and host responses against a variety of pathogens, appear to
be mediated by TNFR1 (3-8).
B
(reviewed in Ref. 12) and of the cell death pathway (10). MADD
(MAP kinase-activating death
domain protein) is another protein that binds to the death
domain of TNFR1. However, by contrast to TRADD, MADD does not cause
cell death or NF-B activation, but specifically stimulates the c-Jun
NH2-terminal (JNK) and extracellular signal-regulated
kinase (ERK) members of the MAP kinase family of protein kinases (13).
Notably, the protein partners with which MADD interacts and the genes
activated through the MADD pathway remain to be elucidated.
. However, gene regulation secondary to the
selective signaling of TNF- through the individual TNF receptors
remains poorly understood. Studies using soluble TNF-, which
stimulates both TNF receptors, have identified E-selectin, interleukin-6, and TNF- itself as TNF--inducible genes
(14-16).
B kinase pathway and NF-B translocation and by activation of the
MAP kinase family, which results in the phosphorylation and
transcriptional activation of AP-1 family members (reviewed in Ref.
17). Although NF-B activation was shown to be critical in the
regulation of the E-selectin and interleukin-6 genes by TNF- (14,
15), an early study implicated a cAMP-response element (CRE) in the
autoregulation of TNF- gene expression (18). This TNF- CRE site
is critical in the regulation of TNF- by multiple signal
transduction pathways and binds ATF-2 and Jun proteins (19, 20), which
become transcriptionally active upon phosphorylation by the p38 and JNK
members of the MAP kinase family of protein kinases (17).
gene transcription. Strikingly, this induction is
dependent upon p38 MAP kinase activity and the binding of ATF-2/Jun
proteins to the TNF- CRE. Consistent with these findings,
overexpression of MADD results in TNF- gene induction, thus linking
signaling through TNFR1 to MAP kinase activation and TNF- gene
induction. Moreover, this study establishes the TNF- CRE site as the
target of TNFR1 signaling and demonstrates the importance of the MAP
kinase signal transduction pathway in TNFR1-mediated TNF- gene transcription.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
200TNF-/CAT construct and the 3'M and C1M TNF-/CAT constructs
(19, 20), the pZ-FLAG control vector and the FLAG-MADD and 15TU
expression vectors (13), and the CMV-
-galactosidase plasmid (12)
have all been previously described. The FLAG-TRADD expression plasmid
was constructed by isolating TRADD by polymerase chain reaction from a
U937 cDNA library and subcloning it into the pZ-FLAG control vector
as described previously (13). The 15TU
DD vector was constructed by
site-directed mutagenesis of residues 1343-1345 of 15TU using
oligonucleotides DD-mut25S
(5'-CGCCTAATGGGAGCGGCGGCCATTGGGCTTGTG-3') and DD-mut25A
(5'-CACAAGCCCAATGGCCGCCGCTCCCATTAGGCG-3') and subcloned into
pZ-FLAG using the restriction enzymes NotI and
EcoRV.
-mercaptoethanol, penicillin, and streptomycin and were transfected
using DEAE-dextran as described previously (20). Twenty-four hours
after transfection, cells were stimulated with 100 units/ml recombinant
human TNF- (rhTNF-) (Genzyme Corp., Cambridge, MA) and harvested
16 h later. Cells were treated with the p38 inhibitor SB203580
where indicated. The SB203580 compound was synthesized based on a
published procedure (21).
where
indicated; nuclear extracts were prepared; and an electrophoretic
mobility shift assay was performed as described previously (22).
Antibody competition assays were performed using an anti-ATF-2 antibody
(a gift from Dr. D. Thanos); antibodies to Jun family members (Santa
Cruz Biotechnology, Inc., Santa Cruz, CA); or antibodies to p50, p65,
and c-Rel (gifts from Dr. N. Rice) as described previously (20). The
synthetic oligonucleotides used in the electrophoretic mobility shift
assay were as follows: 3(L),
5'-GATCCTTCCTCCAGATGAGCTCATGGGTTTCTCCACCAAGGAA- 3';
and PRDII, 5'-GATCCAGTGGGAAATTCCTCA-3'.
as described above, and an RNase protection
assay was performed using murine TNF- and 
-actin probes as
described previously (22).
in the presence or
absence of the p38 inhibitor SB203580 (2.5-20 µM) as
indicated, which was added 1 h prior to stimulation with rhTNF-. Nuclear extracts (10 µg) were subjected to Western blot analysis, and phosphorylated ATF-2 and c-Jun proteins were detected using a phospho-specific antibody kit (New England Biolabs Inc., Beverly, MA) as directed by the manufacturer. p38 MAP kinase was immunoprecipitated from whole cell extracts and used to perform a
kinase assay using GST-ATF-2 as a substrate. Both the
immunoprecipitation and kinase assays were performed using the p38 MAP
kinase assay kit from New England Biolabs Inc.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Gene Expression in L929
Cells--
Human TNF- binds to murine TNFR1, but not to murine
TNFR2 (23), and as a result, treatment of murine cells with rhTNF- results only in TNFR1-mediated effects. Therefore, to determine whether
signaling through TNFR1 alone resulted in the induction of TNF- gene
expression, we stimulated murine L929 fibroblast cells with rhTNF-
and measured TNF- mRNA levels. As shown in Fig.
1A, L929 cells constitutively
expressed a very low level of TNF- mRNA (lane 1),
which was induced after stimulation with rhTNF- (lane 2).
Thus, selective signaling through TNFR1 results in the induction of
TNF- gene expression.
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Fig. 1.
Engagement of TNFR1 stimulates
TNF- gene expression in L929 fibroblasts.
A, induction of TNF- gene transcription by TNFR1
engagement in L929 cells. L929 cells were stimulated with 100 units/ml
rhTNF- for 2 h, and RNA was isolated. Subsequently, an RNase
protection assay was performed, and murine TNF- mRNA levels were
measured. The -actin riboprobe was used to control for equal loading
and processing of RNA. B, TNFR1 engagement induces human
TNF-/CAT reporter genes in L929 cells. L929 cells were transiently
transfected with TNF-/CAT reporter gene constructs containing 200
or 1045 nucleotides 5' to the human TNF- transcription start site.
Twenty-four hours after transfection, cells were treated for 16 h
with 100 units/ml rhTNF-. To control for transfection efficiency,
all cells were cotransfected with CMV--galactosidase, and extracts
were normalized to -galactosidase activity. The experiment shown is
representative of three independent experiments.
promoter sequences required for the
transcriptional activation of the TNF- gene via TNFR1 signaling, we
first transfected L929 cells with a TNF-/CAT reporter gene containing either 1045 or 200 nucleotides upstream of the TNF- mRNA cap site. Consistent with studies in multiple other cell types
and using a variety of inducers (19, 20, 22), 200 nucleotides
upstream of the TNF- transcription start site are sufficient for
maximal inducibility of the gene by TNFR1 engagement in L929 cells
(Fig. 1B). In fact, the 200TNF-/CAT reporter
gene construct was consistently more inducible by rhTNF- than the 1045TNF-/CAT construct. Taken together, these experiments
demonstrate that L929 cells are a physiological system in which to
characterize TNF- autoregulation secondary to TNFR1 signaling and
that 200 nucleotides are sufficient for maximal TNFR1-mediated
induction of the TNF- gene.
Gene Expression--
MADD
recruitment to TNFR1 results in the activation of JNK and ERK MAP
kinase pathways, but does not activate NF-B (13). By contrast, TRADD
interaction with TNFR1 initiates a pathway resulting in NF-B
activation (10). To determine whether the signal transduction pathways
initiated by MADD and/or TRADD resulted in the activation of TNF-
gene expression, we cotransfected MADD or TRADD expression vectors with
the TNF-/CAT reporter gene. As shown in Fig.
2A, overexpression of MADD,
but not TRADD, increased TNF-/CAT reporter activity. Thus,
MADD-stimulated MAP kinase activity activates TNF-
transcription.
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Fig. 2.
MADD stimulates TNF- gene expression. A, MADD, but not TRADD, induces
TNF- gene expression. L929 cells were transiently transfected with
the human 200TNF-/CAT reporter gene and cotransfected with MADD,
TRADD, or control vector and CMV--galactosidase. Thirty-six hours
after transfection, cells were harvested, and CAT assays were performed
after normalization of extracts for -galactosidase expression. The
percent conversion of [14C]chloramphenicol to its
acetylated forms was quantified using a Betagen Betascope and
normalized to the control levels (100%) and then averaged and plotted.
The results displayed are an average from three independent
experiments, and the error bars represent S.E. B,
the MADD death domain is sufficient for activation of TNF- gene
expression. L929 cells were transiently transfected with the human
200TNF-/CAT reporter gene and cotransfected with pFLAG-15TU
(encoding a 320-amino acid protein containing the MADD death domain), a
mutant form of 15TU containing a mutation in the death domain
(15TUDD), or control vector and CMV--galactosidase. Thirty-six
hours after transfection, cells were harvested; CAT assays were
performed after normalization of extracts for -galactosidase
expression; and results were plotted as described above. The experiment
shown is representative of three independent experiments.
by cotransfection
of 15TU with the TNF- reporter. As shown in Fig. 2B, 15TU
activated the TNF- reporter to levels comparable to MADD. However, a
mutant form of 15TU, with a 3-amino acid substitution in the death
domain (15TUDD), was not capable of inducing the TNF-/CAT
reporter (Fig. 2B). Taken together, our results establish the TNF- gene as the first identified gene target of MADD and implicate the involvement of MAP kinase activation in TNFR1 stimulation of TNF-. We note that overexpression of 15TUDD did not abrogate rhTNF- induction of the TNF-/CAT reporter gene (data not shown), consistent with the involvement of other TNFR1-stimulated pathways not
transduced by MADD.
CRE Is Required for Activation of the Gene via
TNFR1--
The TNF- composite CRE/3 promoter element, which is
critical in the regulation of TNF- by a variety of stimuli, binds
ATF-2/Jun proteins (19, 20). Given the facts that ATF-2/Jun become
transcriptionally active upon phosphorylation by JNK and that ATF-2 is
also phosphorylated by p38 MAP kinase (see Ref. 17, for example), we
tested whether the CRE was required for TNFR1-mediated TNF- gene
expression. As shown in Fig.
3A, a mutation in the TNF-
CRE, called C1M, inhibited TNFR1-stimulated TNF-/CAT activity in
L929 cells, whereas a mutation in the adjacent 3-nuclear factor of
activated T cells (NFAT)-binding site, called 3'M, had no effect upon
TNF- gene expression. Similarly, MADD-stimulated TNF-/CAT
reporter activity was also inhibited by mutation of the CRE, but not by
mutation of the 3-NFAT site (Fig. 3B). Thus, the TNF-
CRE site is required for activation of TNF- gene expression
stimulated by TNFR1 or by MADD.
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Fig. 3.
The TNF- CRE is
required for TNFR1- or MADD-stimulated TNF- gene expression. L929 cells were transfected with the
wild-type (WT) human 200TNF-/CAT reporter gene or
TNF-/CAT reporter genes bearing mutations in the CRE (C1M) or the
3 site (3'M) of the TNF- promoter (see diagram at the
bottom). Activation of the promoter by treatment with rhTNF- or by
overexpression of MADD was assessed. A, The wild-type, C1M,
or 3'M TNF-/CAT reporter gene and CMV--galactosidase were
transiently transfected into L929 cells. Twenty-four hours after
transfection, cells were either mock-stimulated (white bars)
or stimulated with rhTNF- (black bars), and CAT assays
were performed and analysed as in Fig. 2. The error bars
represent S.E. The results displayed are an average from three
independent experiments. B, MADD stimulation TNF- gene
expression requires the CRE. The wild-type, C1M, or 3'M TNF-/CAT
reporter gene and CMV--galactosidase were cotransfected with a MADD
expression vector (black bars) or a control vector
(white bars), and 36 h after transfection, cells were
harvested, and CAT assays and analysis were carried out as described
for A.
gene transcription, we next investigated which
activators bind to the CRE in TNFR1-stimulated L929 cells. We prepared
nuclear extracts from L929 cells stimulated with rhTNF- and
performed an electrophoretic mobility shift assay using an
oligonucleotide probe containing the composite CRE/3 site (3(L)).
As shown in Fig. 4A
(lanes 1 and 2), the 3(L) probe bound three
constitutive complexes, which were not inducible by rhTNF-. Using
antibodies to ATF-2 and Jun proteins, we showed that ATF-2 proteins
were contained in the upper two complexes (Fig. 4A,
lanes 3-5, labeled 1 and 2) and that
Jun proteins were contained in the two lower complexes (labeled
2 and 3). In contrast to ATF-2 and Jun,
antibodies to the NF-B proteins p50, p65, and c-Rel did not react
with the 3(L)-binding complexes (Fig. 4A, lanes
8-10). As a positive control for TNF- stimulation of L929
cells and NF-B binding, we used the high affinity NF-B-binding
site, PRDII (24), as a probe. PRDII bound a TNF--inducible complex
(Fig. 4B, compare lanes 1 and 2),
which reacted with antibodies to p50/p65 NF-B proteins in a
supershift assay (lanes 3 and 4). From these
experiments, we conclude that ATF-2/Jun proteins bind constitutively to
the TNF- CRE site in L929 cells.
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Fig. 4.
ATF-2 and Jun proteins bind to the
TNF- CRE in L929 cell nuclear extracts.
A, antibodies to ATF-2 and Jun react with the
3(L)-binding complexes in TNFR1-stimulated L929 nuclear extracts.
Nuclear extracts were prepared from unstimulated L929 cells
(UN) or from cells stimulated with rhTNF- for 2 h.
Binding assays were performed with the 3(L) oligonucleotide probe
and were carried out in the presence or absence of the antibodies as
indicated. The sequence of the composite CRE/3 site included in
3(L) is diagrammed at the bottom of Fig. 3. The numbered
bars to the left of A indicate the three constitutive
3(L)-binding complexes. The ATF-2 and Jun antibodies did not react
with an irrelevant probe that binds Sp1 proteins (data not shown).
B, TNF--inducible NF-B binds to PRDII. Nuclear
extracts were prepared from unstimulated L929 cells (UN) or
from cells stimulated with rhTNF- for 2 h. Binding assays were
performed using the NF-B-binding site (PRDII) as a probe and were
carried out in the presence or absence of the antibodies as indicated.
Antibodies to the NF-B proteins p50 and p65 react with the
TNFR1-inducible PRDII-binding complex.
gene expression and ATF-2
phosphorylation in L929 cells. As shown in Fig.
5A, TNFR1-mediated induction
of the TNF-/CAT reporter was inhibited in a
dose-dependent manner by SB203580, a pyridinylimidazole
that specifically binds to and inhibits p38 MAP kinase (25).
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Fig. 5.
TNFR1 engagement of L929 cells results in p38
MAP kinase-dependent TNF- gene
expression and ATF-2 phosphorylation. A, TNFR1-stimulated
TNF- gene expression is p38 MAP kinase-dependent. L929
cells were transfected with the 200TNF-/CAT reporter gene and
stimulated with rhTNF- as described in the legend to Fig. 1. Where
indicated, cells were pretreated with the p38 inhibitor SB203580 1 h prior to stimulation with rhTNF-. For all experiments, a
CMV--galactosidase construct was cotransfected, and extracts were
normalized for -galactosidase activity to control for transfection
efficiency. Results of three independent experiments were normalized to
the TNF--induced levels of the 200TNF-/CAT reporter gene in
each experiment in the absence of inhibitor (100%) and then averaged
and plotted. An ~50% inhibition of TNF-/CAT reporter activity was
achieved at a concentration of 10 µM SB203580. The
error bars represent S.E. B, TNFR1-mediated
phosphorylation of endogenous ATF-2, but not c-Jun, is
p38-dependent in L929 cells. Nuclear extracts were prepared
from L929 cells that were mock-treated (untreated (UN)) or
treated with the indicated concentrations of the p38 inhibitor SB203580
1 h prior to stimulation with 1000 units/ml rhTNF-. Western
blot analysis was performed using phospho-specific antibodies
recognizing ATF-2 (upper panel) and c-Jun (lower
panel). The positions of the phosphorylated proteins are
indicated. The results displayed are representative of three
independent experiments. Quantification of the blot by densitometry
revealed that a 50% inhibition of ATF-2 phosphorylation was achieved
at a concentration of 10 µM SB203580, which is identical
to the effects of the inhibitor on TNF-/CAT reporter gene expression
using this concentration (see A). C,
TNFR1-dependent induction of cellular p38 MAP kinase
activity. L929 cells were stimulated with 1000 units/ml rhTNF-;
whole cell extracts were prepared; p38 MAP kinase was
immunoprecipitated; and a kinase assay was performed using GST-ATF-2 as
the substrate. The reactions were then subjected to Western blot
analysis, and phosphorylated ATF-2 was visualized by chemiluminescence.
The experiment displayed shows a 3.2-fold increase in phosphorylated
ATF-2 levels (compare lanes 1 and 3), which was
inhibited ~2-fold by pretreatment of the cells with 10 µM SB203580 (compare lanes 3 and
4). The position of the phosphorylated protein is indicated
on the left. The results displayed are representative of three
independent experiments.
transcription, we performed a Western
blot analysis using phospho-specific antibodies to ATF-2. Treatment of
L929 cells with rhTNF- resulted in the phosphorylation of endogenous
ATF-2 (Fig. 5B, upper panel, lane 2),
whereas addition of increasing amounts of SB203580 resulted in a
dose-dependent inhibition of ATF-2 phosphorylation
(lanes 3-7). Notably, several groups have reported
inhibition of JNK activity by higher doses of SB203580 (26, 27).
However, we did not observe an inhibitory effect of our preparation of
the p38 inhibitor on the phosphorylation of c-Jun, even at
concentrations of up to 20 µM (Fig. 5B,
lower panel).
and immunoprecipitated cellular proteins with
an anti-p38 MAP kinase antibody. A kinase assay using GST-ATF-2 as a
substrate was then performed on the immunoprecipitated samples, and
they were analyzed by Western blotting. Using a phospho-specific ATF-2
antibody, we demonstrated that TNFR1 engagement resulted in an increase
in p38-mediated ATF-2 phosphorylation (Fig. 5C, compare
lanes 1 and 3). We demonstrated the specificity
of this effect by pretreating the cells with 10 µM
SB203580, which, as expected, inhibited the TNFR1-mediated increase in
ATF-2 phosphorylation (Fig. 5C, compare lanes 3 and 4). Taken together, this series of experiments links
TNFR1-mediated activation of p38 MAP kinase to the
p38-dependent phosphorylation of ATF-2 and the induction of
TNF- gene expression.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
B activation, and the
induction of apoptosis (see Ref. 26, for example). Here, we have shown
that TNFR1 engagement leads to TNF- gene transcription through the
p38-dependent phosphorylation and binding of ATF-2/Jun to
the TNF- CRE promoter element. Thus, the p38 MAP kinase pathway is
the critical arm of the TNFR1 signaling pathway involved in the
transcriptional autoregulation of TNF-. Recent work from other
laboratories supports a role for p38 MAP kinase in TNF--mediated gene activation. For example, disruption of the Mkk3 gene, a
specific activator of p38 MAP kinase, causes a selective defect in
TNF--stimulated p38 MAP kinase activation and blocks TNF-
induction of the interleukin-1 and -6 genes (27). Consistent with
earlier studies showing the importance of the CRE and the binding of
ATF-2/Jun in TNF- gene regulation in activated T cells (19, 20), p38
has also recently been shown to be involved in the transcriptional and
translational control of TNF- in T cells (28).
-inducing kinase result in the activation of NF-B
in a wide spectrum of cell types (3-5, 7). Our experiments argue
against a role for NF-B in the autoregulation of TNF- since
overexpression of TRADD, which transduces signals resulting in the
activation of NF-B, did not result in the induction of TNF- gene
expression. Furthermore, we did not detect inducible NF-B binding
activity to the TNF- CRE/3 site, which bears a weak sequence
similarity to a consensus NF binding site (22). Rather, we have
shown that ATF-2/Jun bind to the CRE site, which is required for
TNFR1-mediated TNF- gene expression.
gene
regulation. MADD signaling has previously been shown to activate the
ERK and JNK MAP kinase pathways (13). Consistent with its role in MAP
kinase activation, we show that MADD activation of TNF- gene
expression is dependent upon an intact CRE site. Given that MADD
stimulates the JNK pathway, it is likely that MADD mediates
phosphorylation of ATF-2 via JNK activation and thereby induces
transcription of the TNF- gene. We note that we could not observe
MADD activation of the p38 and p38 MAP kinase forms, although we
did observe inhibition of MADD-stimulated TNF- gene expression by
SB203580 (data not shown). Interestingly, SB203580 does not inhibit
JNK1, but can inhibit JNK2 (29). Thus, the observation that SB203580
did not inhibit the activation of c-Jun (Fig. 5B) may
reflect the activation of both JNK1 and JNK2 by rhTNF-, whereas
MADD may activate only JNK2. Taken together with our demonstration
that TNFR1-mediated activation of TNF- requires p38 activation,
these data indicate that TNFR1 stimulation of TNF- gene expression
involves both MADD-dependent activation of the JNK pathway
and MADD-independent activation of p38 MAP kinase.
itself display an overlapping set of
pathologies. For example, mice deficient in TNFR1 or TNF-
demonstrate abnormal organization of splenic B cell follicles (30), are
more susceptible to a variety of intracellular pathogens including
Listeria and tuberculosis, and are relatively resistant to
developing septic shock (8, 31-33). Thus, TNFR1-stimulated TNF-
gene expression is central to normal immunological processes as well as
to host defense. The autoregulation of TNF-, which begins at the
level of the transcriptional induction of the gene, is likely to be
crucial in several of these disease processes.
autoregulation. These
molecular targets may thus prove useful in the therapeutic modulation
of TNF- gene expression in cases where too much or too little
TNF- is associated with variable patterns of disease pathogenesis.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
, recombinant human TNF-;
TNFR, tumor necrosis
factor receptor;
MAP, mitogen-activated protein;
JNK, c-Jun
NH2-terminal kinase;
ERK, extracellular signal-regulated
kinase;
CRE, cAMP-response element;
CAT, chloramphenicol
acetyltransferase;
CMV, cytomegalovirus;
DD, death domain;
GST, glutathione S-transferase.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1.
Aggarwal, B. B., and Puri, R. K.
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Human Cytokines: Their Role in Disease and Therapy
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Loetscher, H.,
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and Shalaby, R.
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Engelmann, H.,
Hotmann, H.,
Brakebusch, C.,
Avni, Y. S.,
Sarov, I.,
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