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J Biol Chem, Vol. 274, Issue 33, 22911-22914, August 13, 1999
From the Department of Microbiology and Immunology, Pennsylvania
State University College of Medicine, Hershey, Pennsylvania 17033
The tax gene product of human T-cell
leukemia virus type I induces activation of transcription factor
NF- The type I human T-cell leukemia virus
(HTLV-I)1 transforms human
T-cells, which is associated with the development of an acute T-cell
malignancy termed adult T-cell leukemia (1). HTLV-I encodes a
regulatory protein, Tax, which plays a central role in the induction of
host cell transformation (1). Tax alters the expression of a large
number of cellular genes involved in cell growth and survival, which
appears to contribute to the oncogenic activity of this viral protein
(2, 3). Lacking DNA binding activity, Tax induces the target genes
indirectly by modulating the activity of specific host transcription
factors (3, 4). Induction of many cellular genes by Tax is mediated
through the transcription factor NF- In resting T-cells, as well as most other cell types, NF- We and others have shown recently that the IKK is constitutively
activated in HTLV-I-infected or Tax-expressing T-cells (22-25). This
action of Tax results in persistent degradation of I Plasmids and Antibodies--
The pcDNA-HA vector was
constructed by inserting a copy of the influenza hemagglutinin (HA)
epitope tag (YPYDVPDYA) together with the translation initiation codon
(ATG) into the mammalian expression vector pcDNA3.1 (Invitrogen).
To generate pcDNA-HA-NEMO/IKK Immunoprecipitation (IP) and Immunoblotting Assays--
Human
293 kidney carcinoma cells were seeded in 0.1% gelatin-treated
six-well plates (1 × 105 cells/well) and transfected
using DEAE-dextran with the indicated cDNA expression vectors. The
DNA amounts used for the transfections were normalized based on the
expression efficiency of each of the expression vectors: 50 ng for
IKK NEMO/IKK Different Sequences of NEMO/IKK NEMO/IKK
We then examined the effect of NEMO/IKK
To assess the role of upstream kinases in the
IKK A Mutant Form of Tax, Defective in IKK Activation, Is Inefficient
in NEMO/IKK HTLV-I-encoded Tax protein is a potent activator of the cellular
transcription factor NF- It remains to be further studied how the recruitment of Tax to IKK
complex triggers IKK activation. A recent study suggests that Tax also
physically interacts with MEKK1 and activates the catalytic activity of
this IKK-activating kinase (22). Thus, an intriguing model is that Tax
recruits upstream kinases, such as MEKK1, to the IKK complex, thus
triggering phosphorylation-dependent IKK activation.
However, interaction of Tax with MEKK1 appears to be relatively weak
under the stringent IP conditions used in this study (Fig. 1). We have
shown previously that NIK is functionally involved in Tax activation of
IKK, although this kinase also does not strongly bind to Tax. It
remains to be examined whether the weak interaction of Tax with MEKK1
or NIK is sufficient to recruit these upstream kinases to IKK.
Nevertheless, we have shown that the IKK We thank W. C. Greene, A. Isrëal,
S. Yamaoka, M. Karin, and D. Wallach for cDNA expression vectors.
The anti-Tax hybridoma was kindly provided by the AIDS Research and
Reference Program, NIAID, National Institutes of Health.
*
This work was supported by Public Health Service Grant 1 R01
CA68471 (to S.-C. S.).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.
The abbreviations used are:
HTLV-I, human T-cell
leukemia virus type I;
IKK, I
COMMUNICATION
IKK
Serves as a Docking Subunit of the I
B Kinase (IKK) and
Mediates Interaction of IKK with the Human T-cell Leukemia Virus Tax
Protein*
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B, which contributes to deregulated expression of various
cellular genes. Tax expression triggers persistent phosphorylation and
degradation of the NF-B inhibitory proteins IB
and IB
,
resulting in constitutive nuclear expression of NF-B. Recent studies
demonstrate that Tax activates the IB kinase (IKK), although the
underlying mechanism remains unclear. In this report, we show that Tax
physically interacts with a regulatory component of the IKK complex,
the NF-B essential modulator or IKK
(NEMO/IKK). This molecular
interaction appears to be important for recruiting Tax to the IKK
catalytic subunits, IKK and IKK. Expression of NEMO/IKK
greatly promotes binding of Tax to IKK and IKK and stimulates
Tax-mediated IKK activation. Interestingly, a mutant form of Tax
defective in IKK activation exhibited a markedly diminished level of
NEMO/IKK association. These findings suggest that the physical
interaction of Tax with NEMO/IKK may play an important role in
Tax-mediated IKK activation.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B (3), a key regulator of genes
involved in cell activation, proliferation, and survival (for recent
reviews, see Refs. 5-7).
B is
sequestered as an inactive precursor by association with specific inhibitors, including IB, IB, and related proteins (8). Induction of NF-B nuclear expression by cytokines and T-cell mitogens is mediated by activation of a multisubunit IB kinase (IKK)
(9-11). The IKK complex is composed of two catalytic subunits, IKK
(12-14) and IKK (14-16), and a noncatalytic subunit termed IKK
(also named NF-B essential modulator (NEMO) and IKK-associated protein 1, hereafter called NEMO/IKK) (17-19). Additional proteins have been shown to be physically associated with the IKK complex, which
include MEK kinase 1 (MEKK1), NF-B-inducing kinase (NIK) (12, 14,
20), and IKK complex-associated protein (21). Upon activation, IKK
phosphorylates IB and IB at two regulatory N-terminal
serine residues, causing rapid ubiquitination and proteolysis of these
NF-B inhibitors, which allows the released NF-B to enter the
nucleus and activate target genes (10, 11).
B and IB and constitutive nuclear expression of NF-B (26-30). Tax has been shown to induce the catalytic activity of both IKK and IKK, although the underlying mechanism remains unclear (17). In this
paper, we show that Tax physically interacts with NEMO/IKK, which
facilitates the recruitment of Tax to the catalytic subunits IKK and
IKK and promotes Tax-mediated activation of IKK.
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
, the murine NEMO cDNA
(provided by Drs. S. Yamaoka and A. Isrëal (17)) was subcloned
into the pcDNA-HA vector downstream of the HA tag. Truncation
mutants of NEMO/IKK were generated by restriction digestion and
designated by the specific amino acid residues retained in the mutant
proteins. For example, NEMO/IKK-(1-312) contains the N-terminal 312 amino acids. pCMV4-HA-NIK was generated by inserting HA-tagged human
NIK cDNA (provided by Dr. David Wallach (20)) in the pCMV4 vector
(31). pCMV4-HA-IB was described previously (32). The
pcDNA-HA-IKK, pcDNA-HA-IKK, and pcDNA-HA-MEKK1 were
provided by Dr. M. Karin. The pCMV4-Tax, pCMV4-TaxM22, and pCMV4-TaxM47
were provided by Dr. W. C. Greene (33). The anti-HA and
anti-IKK monoclonal antibodies were from Roche Molecular Biochemicals and Imgenex Corp., respectively. The anti-Tax monoclonal antibody was prepared from a hybridoma (168B17-46-34) provided by the
AIDS Research and Reference Program, NIAID, National Institutes of
Health. All the other antibodies were purchased from Santa Cruz
Biotechnology, Inc.
, IKK, MEKK1, and NIK; 50-200 ng for NEMO/IKK and its
truncation mutants; 0.5 µg for Tax and its mutants. After 40 h,
recipient cells were lysed in RIPA buffer (50 mM Tris-HCl,
pH 7.4, 150 mM NaCl, 1% Nonidet P-40, 0.5% sodium
deoxycholate, 0.1% SDS, 1 mM EDTA, 1 mM
phenylmethylsulfonyl fluoride, 1 mM dithiothreitol, 0.01 volume of a protease inhibitor mixture (34)). The RIPA buffer was also
used to prepare whole-cell extracts from the HTLV-I-infected SLB-1
cells (24). IP was performed as described previously (34), and the
precipitated proteins were analyzed by SDS-polyacrylamide gel
electrophoresis followed by immunoblotting. For immunoblotting analyses
of IB phosphorylation, 293 cells were transfected in 24-well
plates. Whole-cell extracts were prepared in ELB buffer (34)
supplemented with phosphatase inhibitors and analyzed by immunoblotting
(34).
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
Serves as a Primary Target of Tax in the IKK
Complex--
Prior studies suggest that Tax interacts with the IKK
catalytic subunits IKK and IKK (23) as well as the upstream
kinase MEKK1 (22). However, since the IKK components are present in a
large complex in intact cells, it remains unknown which component serves as the primary target of Tax. To address this question, co-IP
was performed using a high stringency binding buffer (RIPA) to assess
the relative binding affinity of Tax with the different molecular
components of the IKK complex. Tax was transiently expressed in 293 cells either alone or together with each of the known IKK components,
including IKK, IKK, NEMO/IKK, MEKK1, and NIK, all of which
were tagged with the HA antigenic epitope. In the absence of an IKK
component, Tax was not precipitated by the anti-HA antibody (Fig.
1A, lane 3),
although this protein was readily precipitated by the anti-Tax antibody
(lane 2), demonstrating the specificity of the antibodies.
Under these conditions, a small amount of Tax was coprecipitated with
IKK and NIK (lanes 4 and 8). Coprecipitation of Tax with IKK and MEKK1 was also detected after an extended exposure time (data not shown). Importantly, the IP assays revealed a
remarkably higher amount of Tax coprecipitated with NEMO/IKK (Fig.
1A, lane 6). Thus, while Tax may weakly bind to
various components of the IKK complex, NEMO/IKK appears to be a
major target of this viral transactivator protein. To address the
physiological relevance of this finding, we examined the interaction
between Tax and NEMO/IKK in HTLV-I-infected T-cells. As expected,
Tax was readily detected from the immune complex precipitated by the anti-Tax antibody (Fig. 1C, lane 2), but not from
that precipitated by a preimmune serum (lane 1). More
importantly, a significant amount of Tax was coprecipitated with IKK
by an IKK-specific antibody (lane 3). These findings
clearly demonstrated that Tax stably binds to NEMO/IKK in both
transfected and HTLV-I-infected cells.
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Fig. 1.
Interaction of NEMO/IKK
with Tax in transfected and HTLV-I infected cells. A,
293 cells were transfected with the indicated cDNA expression
constructs (lanes 2-8) or an empty vector (lane
1). Except Tax, all the other proteins were tagged with the HA
epitope. Cell extracts were subjected to IP using anti-HA followed by
immunoblotting (IB) analyses using anti-Tax. The
coprecipitated Tax protein is indicated by the arrow.
B, the cell extracts used in A were directly analyzed by
immunoblotting with anti-HA (upper panel) or anti-Tax
(lower panel) to detect the expression of the various
HA-tagged IKK components and Tax, respectively. Two major nonspecific
bands are indicated by ns in this and all the subsequent
figures. C, whole-cell extracts isolated from the
HTLV-I-infected SLB-1 cells were subjected to IP using either a
preimmune serum (PI) or antisera specific for Tax
(Tax) or IKK (IKK). The precipitated
proteins were analyzed by immunoblotting with anti-Tax to examine its
coprecipitation with IKK.
Are Involved in Binding to Tax
and IKK--
NEMO/IKK is known to form a stable complex with
IKK and IKK in vivo (17, 18). To map the regions of
NEMO/IKK involved in binding to the IKK catalytic subunits and Tax,
progressive truncations were generated from both the N and C termini of
NEMO/IKK. Deletion of the N-terminal 110 amino acids of NEMO/IKK
did not affect its binding to IKK (Fig.
2A, lane 3) or Tax
(lane 10). Deletion of up to 292 amino acids from the C
terminus also did not affect the IKK association (lanes
4-6), although further removal of 8 amino acids generated a
mutant (1-112) that no longer bound IKK (lane 7). In
contrast to that seen with IKK, Tax interaction with NEMO/IKK
required the C-terminal sequences of NEMO/IKK. Removal of 100 amino
acids from this end of the molecule significantly reduced, although not
abolished, its interaction with Tax (Fig. 2A, lane
11). This low level binding activity was also detected between Tax
and an IKK mutant lacking its C-terminal 157 amino acids (lane
12). However, further deletion of 135 or more amino acids from
this end generated IKK mutants (1-120 and 1-112), which completely
lost Tax-binding activity (lanes 13 and 14). Of
note, IKK-(1-120) still retained its IKK binding activity. Thus,
while the N-terminal 120 amino acids of NEMO/IKK are sufficient for
binding to IKK, the C-terminal region is required for strong interaction with Tax.
View larger version (66K):
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Fig. 2.
Different sequences of
NEMO/IKK are required for binding to Tax and
IKK. A, 293 cells were
transfected with HA-tagged full-length NEMO/IKK (FL) or
its truncation mutants together with either IKK (lanes
1-7) or Tax (lanes 8-14). Cell extracts were
subjected to IP with anti-IKK (lanes 1-7) or anti-HA
(lanes 8-14) followed by immunoblotting (IB)
using anti-HA (lanes 1-7) or anti-Tax (lanes
8-14). Since the full-length NEMO/IKK migrated closely with
the immunoglobulin heavy chain (IgH), lanes 1 and
2 were run in a separate gel. The coprecipitated NEMO/IKK
proteins are labeled with arrowheads. B, extracts
used in the corresponding lanes of A were subjected to
direct immunoblotting using anti-HA to monitor the expression of the
full-length and truncated forms of NEMO/IKK.
Facilitates Binding of Tax to the Catalytic Subunits of
IKK and Promotes Tax-mediated IKK Activation--
To assess the role
of the interaction between Tax and NEMO/IKK in IKK activation, we
examined the effect of NEMO/IKK on Tax interaction with the
catalytic subunits of IKK and on Tax-mediated IKK activation. For these
studies, Tax was coexpressed with HA-tagged IKK or IKK together
with either the full-length NEMO/IKK or its C-terminal truncation
mutant, 1-312. We found that the low level interaction of IKK and
IKK with Tax could be more readily detected when the IP was
performed using the anti-Tax antibody (Fig.
3A, lanes 2 and
5). More importantly, the interaction of Tax with both
IKK and IKK was remarkably enhanced by the full-length NEMO/IKK (lanes 3 and 6). Parallel
immunoblotting assays showed that NEMO/IKK did not affect the
expression level of the IKKs (data not shown). Furthermore, this
stimulatory effect was only weakly detected with the
NEMO/IKK-(1-312) (lanes 4 and 7), a C-terminal truncation mutant exhibiting reduced affinity in Tax binding
(see Fig. 2A).
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Fig. 3.
NEMO/IKK promotes
interaction of Tax with IKK and
IKK and stimulates Tax-mediated
IKK activation. A, 293 cells
were transfected with Tax together with HA-IKK (lanes
2-4) or HA-IKK (lanes 5-7), either in the absence
(
) or presence of the full-length (FL) or C-terminal
truncated (1-312) NEMO/IKK. Lane 1 was a control
transfected with an empty vector. Cell extracts were subjected to IP
with anti-Tax followed by detection of the coprecipitated IKKs by
Immunoblotting (IB) with anti-HA. B, 293 cells
were transfected with HA-IKK (25 ng) together with either an empty
vector (lane 1) or the indicated amounts of Tax and
HA-tagged NEMO/IKK constructs. All the cells also received the
HA-IB expression vector (0.12 µg). Cell extracts were subjected
to immunoblotting using anti-IB (upper panel), anti-HA
(middle panel), or anti-Tax (lower panel). Basal
and phosphorylated (P) forms of IB and IKK, the
full-length (FL) and truncated (1-312) NEMO/IKK, as well
as Tax, are indicated. Note that IB and IB-P were detected
by both the anti-IB (upper panel) and anti-HA
(lower panel) antibodies. C, 293 cells were
transfected with IKK together with an empty vector (lane
1) or full-length NEMO/IKK (lane 2) in the absence
of Tax, and the IB and NEMO/IKK proteins were analyzed by
immunoblotting using anti-IB (upper panel) or anti-HA
(lower panel). IKK is not shown in the figure.
D, 293 cells were transfected with HA-tagged IB and
the indicated cDNA expression vectors (DNA amounts were as
described for lane 5 of B). The cells were also
transfected with the indicated amounts of a dominant-negative NIK
(DN-NIK). The transfected IB and Tax proteins were
analyzed by immunoblotting using anti-HA (upper panel) and anti-Tax
(lower panel), respectively.
on Tax-mediated IKK
activation by measuring the in vivo phosphorylation of its
substrate IB. In this regard, the in vivo IB
phosphorylation could be detected by immunoblotting since the
phosphorylated IB migrates more slowly on SDS gels (27, 35-37).
As we reported previously (24), expression of IKK alone or together
with Tax in 293 cells did not induce appreciable IB
phosphorylation (Fig. 3B, upper panel,
lanes 1 and 2). However, when these cells were
cotransfected with the full-length NEMO/IKK, the IKK kinase
activity was markedly induced, resulting in the potent phosphorylation
of the substrate IB (upper panel, lanes 5 and 6, IB-P). Degradation of IB became evident when a higher dose of NEMO/IKK was used (lane 6, upper panel). We also observed that Tax induces the
autophosphorylation of IKK in the presence of NEMO/IKK
(middle panel, lanes 5 and 6,
IKK-P). These functional effects were not significantly
detected with the NEMO/IKK-(1-312) (lanes 3 and
4). Furthermore, NEMO/IKK was unable to activate IKK
in the absence of Tax (Fig. 3C). Together, these results
strongly suggest that NEMO/IKK promotes association of Tax with the
IKK catalytic subunits and stimulates Tax-mediated IKK activation.
-dependent induction of IKK by Tax, we examined
the effect of a dominant-negative NIK (DN-NIK) on the in
vivo phosphorylation of IB triggered by Tax (Fig.
3D). As expected, phosphorylated form of IB was readily detected in cells transfected with IKK together with NEMO/IKK and Tax (lane 1). Cotransfection of the DN-NIK
led to a partial inhibition of the IB phosphorylation. Thus, it
is likely that Tax-mediated activation of IKK may involve both its physical interaction with IKK and the participation of upstream kinases.
Binding--
To further assess the functional
importance of Tax interaction with NEMO/IKK, we examined the ability
of two well characterized Tax mutants, M22 and M47 (33), to interact
with NEMO/IKK. The M22 is defective in IKK activation and induction
of NF-B nuclear expression, while M47 remains competent in these
functions (22-25). Interestingly, co-IP assays revealed that while the
wild type Tax and M47 both strongly interacted with NEMO/IKK (Fig.
4, upper panel, lanes
2 and 4), only a marginal NEMO/IKK binding activity was detected with M22 (lane 3). Thus, the physical
interaction of Tax with NEMO/IKK is well correlated with its
ability to activate the IKK catalytic subunits.
View larger version (47K):
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Fig. 4.
Interaction of NEMO/IKK
with wild type and mutant forms of Tax. 293 cells were
transfected with HA-tagged NEMO/IKK together with the wild type Tax
(TaxWT) or its mutants M22 and M47. Cell extracts were
subjected to IP with anti-HA followed by analyzing the coprecipitated
Tax proteins by immunoblotting with anti-Tax (upper panel).
The lower panel shows a direct immunoblotting analysis of
the transfected Tax proteins using anti-Tax. Wild type Tax and its
mutants are indicated by the arrows.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B. Tax activation of NF-B involves phosphorylation and degradation of the NF-B inhibitory proteins IB and IB (26-30). Tax activates the catalytic activity of IKK in both transiently transfected and HTLV-I-transformed cells (22-25). The mechanism by which Tax activates IKK remains elusive. A
recent study suggests that the NEMO/IKK subunit of IKK is essential for Tax-mediated NF-B activation, although it is unclear how this
noncatalytic signaling protein participates in Tax activation of IKK
(17). Our current data demonstrate that NEMO/IKK physically interacts with Tax in both transfected 293 cells and HTLV-I-infected T-cells. Under stringent IP conditions, NEMO/IKK exhibited markedly higher Tax binding activity than various other IKK components (Fig. 1).
The functional importance of this physical interaction in Tax-mediated
activation of IKK is supported by the experiments performed with Tax
mutants (Fig. 4). The M22 mutant, known to be defective in IKK
activation (22-25), exhibits strikingly reduced binding to
NEMO/IKK. How could the binding of NEMO/IKK to Tax contribute to
Tax activation of IKK? One potential mechanism is that NEMO/IKK
serves as an adaptor molecule to recruit Tax to the IKK catalytic
subunits. As shown in Fig. 2, the C-terminal region of NEMO/IKK is
required for its strong binding to Tax, whereas the N-terminal region
of NEMO/IKK mediates interaction with IKK. Although further
studies are required to demonstrate that NEMO/IKK can form a
heterotrimer with Tax and IKK (or IKK), our current data show
that NEMO/IKK indeed promotes the binding of Tax to IKK and
IKK as well as stimulates the Tax-mediated IKK activation (Fig. 3).
Furthermore, these functions were not significantly detected with a
NEMO/IKK C-terminal truncation mutant, 1-312, which exhibits
markedly reduced Tax binding activity.
-dependent IKK
activation by Tax is at least partially sensitive to DN-NIK. This
finding suggests that Tax activation of IKK may involve both
Tax/IKK physical interaction and activation or recruitment of
upstream kinases.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed. Tel.: 717-531-4164;
Fax: 717-531-6522; E-mail: sxs70@psu.edu.
ABBREVIATIONS
B kinase;
NEMO, NF-B essential
modulator;
MEK, mitogen-activated protein kinase/extracellular
signal-related kinase kinase;
MEKK1, MEK kinase 1;
NIK, NF-B-inducing kinase;
DN-NIK, dominant-negative NIK;
IP, immunoprecipitation;
HA, hemagglutinin;
RIPA, radioimmune precipitation
buffer.
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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