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Mol Cell Biol, March 1998, p. 1408-1415, Vol. 18, No. 3
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The J Domain of Simian Virus 40 Large T Antigen Is
Required To Functionally Inactivate RB Family Proteins
Juan
Zalvide,
Hilde
Stubdal,
and
James A.
DeCaprio*
Dana-Farber Cancer Institute and Harvard
Medical School, Boston, Massachusetts 02115
Received 23 September 1997/Returned for modification 29 October
1997/Accepted 19 December 1997
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ABSTRACT |
Transformation by simian virus 40 large T antigen (TAg) is
dependent on the inactivation of cellular tumor suppressors.
Transformation minimally requires the following three domains: (i) a
C-terminal domain that mediates binding to p53; (ii) the LXCXE domain
(residues 103 to 107), necessary for binding to the retinoblastoma
tumor suppressor protein, pRB, and the related p107 and p130; and (iii) an N-terminal domain that is homologous to the J domain of DnaJ molecular chaperone proteins. We have previously demonstrated that the
N-terminal J domain of TAg affects the RB-related proteins by
perturbing the phosphorylation status of p107 and p130 and promoting
the degradation of p130 and that this domain is required for
transformation of cells that express either p107 or p130. In this work,
we demonstrate that the J domain of TAg is required to inactivate the
ability of each member of the pRB family to induce a G1
arrest in Saos-2 cells. Furthermore, the J domain is required to
override the repression of E2F activity mediated by p130 and pRB and to
disrupt p130-E2F DNA binding complexes. These results imply that while
the LXCXE domain serves as a binding site for the RB-related proteins,
the J domain plays an important role in inactivating their function.
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INTRODUCTION |
Simian virus 40 (SV40) large T
antigen (TAg) can transform a variety of cell types. Manifestations of
the transformed phenotype include cell immortalization, growth to a
high density, reduced requirement for serum, anchorage independence,
and the ability to form tumors in various animal models. TAg achieves
this transformation by targeting negative regulators of cell growth,
including p53 and the RB family (pRB, p107, and p130). p53 and pRB are
well-established tumor suppressor proteins, and their corresponding
genes are commonly lost or mutated in human cancer. While p107 and p130
inactivation likely contributes to TAg-mediated transformation (see
below), there is little evidence that these proteins are tumor
suppressors. However, loss of p130 was recently reported in a human
lung cancer cell line (12).
TAg contains at least three transforming domains. A C-terminal domain
extending from approximately residue 350 to residue 550 binds to and
inactivates p53 (22, 31, 42, 52). The LXCXE domain (residues
103 to 107) mediates binding to the retinoblastoma family proteins pRB,
p107, and p130 (5, 6, 9, 19, 51). Mutations within TAg that
disrupt binding to p53 or pRB render it unable to fully transform cells
(46). An intact LXCXE domain is required for TAg to
transform fibroblasts derived from Rb-1 knockout mice
(3, 51). This result implies that p130 and p107, in addition
to pRB, are likely to be relevant targets of TAg during the
transforming process. In addition to the LXCXE and p53 binding domains,
the N-terminal 82 residues of TAg, encoded by the first exon and shared
with small t antigen, are required for transformation (28).
Until recently, the mechanism by which the N terminus contributes to
transformation was unknown.
The N terminus of TAg shares sequence homology with the J domain of the
DnaJ (heat shock protein 40 [Hsp40]) family of molecular chaperones
(20). The J domain consists of approximately 70 residues that bind to and stimulate the ATPase activity of specific Hsp70/DnaK family members (47). The residues
histidine-proline-aspartate (HPD) are absolutely conserved within the J
domain of all known DnaJ homologs (reviewed in reference
39). Substitution mutations in any of these residues
render the J domain defective in activating Hsp70. Notably, all known
polyomavirus large TAg homologs contain the residues HPD within the
first exon (32). Several lines of evidence suggest that the
N terminus of TAg behaves as a J domain. First, like cellular DnaJ
proteins, SV40 TAg can bind specifically to a member of the Hsp70
family of heat shock proteins (36). Second, point mutations
in the highly conserved HPD residues within the N-terminal J-domain
homology region of TAg disrupt binding to Hsc70 (2).
Furthermore, in an in vitro assay, the N termini of SV40 TAg and small
t antigens were able to stimulate the ATPase activity of a variety of
Hsp70 homologs (41). Finally, the J domains of SV40, JC
virus, and BK virus could each functionally substitute for the J domain
of Escherichia coli DnaJ and restore the ability of the host
cell to form bacteriophage lambda plaques (21).
Collectively, these results strongly suggest that the N termini of the
polyomavirus large TAgs function as J domains.
We have previously demonstrated that the J domain of TAg mediates a
perturbation of the phosphorylation status of p130 and p107 and induces
rapid turnover of p130 (44, 45). p130 and p107, like pRB,
are normally phosphorylated in a cell cycle-dependent manner in the
mid- to late G1 phase (1, 26, 50). In cells expressing TAg, the normal cell cycle-dependent phosphorylation of p130
and p107 is disrupted, and only the fastest-migrating species of p130
and p107 can be detected. These effects of TAg are absolutely dependent
upon an intact J domain; they are abolished by point mutations in the
conserved HPD motif and are restored when the N terminus of TAg is
replaced with a cellular J domain (44).
Our previous studies also indicated that the J domain of TAg
contributed to TAg-mediated transformation. Mouse embryo fibroblasts (MEFs) expressing TAg with single-amino-acid substitutions in the
conserved HPD motif of the J domain were unable to grow to a high cell
density or in media containing reduced (1%) serum (44).
However, replacement of the N terminus of TAg with intact J domains
from human DnaJ homologs restored the ability of TAg to fully transform
normal MEFs (44). In a separate study, TAg constructs with
deletions within the N terminus or substitutions in the HPD motif were
also unable to transform C3H10T1/2 and REF52 cells (41).
The studies done to date indicate that the J domain of TAg contributes
to transformation and affects the phosphorylation status and stability
of RB family proteins. Based on this, we considered that the J domain
may contribute to other effects of TAg on the RB family. Overexpression
of pRB, p107, and p130 can induce an arrest in the G1 phase
of the cell cycle in a number of cell lines (4, 14, 53, 54).
This G1 arrest can be overcome by expression of E2F. It can
also be overcome by expression of cyclins and cdks that phosphorylate
and inactivate pRB family proteins and by the viral oncoprotein
adenovirus E1A (1, 4, 14, 35, 50).
At least some of the growth-suppressing properties of the pRB family
are dependent on their interaction with the E2F family of transcription
factors. E2F-DP heterodimers bind to specific DNA sequences found in
the promoters of many genes required for cell cycle progression. RB
family proteins bind to these E2F-DP complexes on DNA and repress E2F
transcriptional activity during the G0/G1 phase
of the cell cycle. These complexes, which can be detected by gel
retardation assays, are disrupted by wild-type TAg, but not by TAg
mutants that fail to bind to the RB family proteins (51).
E2F-dependent transactivation occurs during the
G1/S-phase transition of the cell cycle, when the
repressive RB family proteins have been inactivated by
phosphorylation. Experimentally, this can be studied by assaying the
ability of RB family proteins to repress transcription from an E2F
promoter driving a reporter gene. In such assays, the RB-mediated
repression can be relieved by expression of E2F, cyclins or cdks, or
adenovirus E1A (14, 34, 35, 54).
In many assays of RB family protein function, wild-type TAg can
inactivate pRB, as well as p107 and p130, when these proteins have been
included. The ability of TAg to inactivate pRB function requires the
LXCXE domain, which mediates binding to the RB family proteins. In this
study, we address the role of the J domain of TAg in the inactivation
of the RB family proteins.
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MATERIALS AND METHODS |
Cells.
Cells were cultured in Dulbecco's modified Eagle's
medium containing 10% fetal clone serum (Hyclone), 100 U of penicillin per ml, and 100 µg of streptomycin per ml. MEFs expressing wild-type TAg or various TAg mutants have been described previously
(44). Saos-2 cells, an Rb-1 (
/) osteosarcoma
line, were obtained from the American Type Culture Collection. Saos-2
cells were transfected by the calcium phosphate precipitation method.
The cells were incubated with the precipitate for 6 h, washed
twice with complete medium, and cultured for an additional 36 h.
Cell cycle analysis and luciferase assays of transfected cells were
performed as described previously (15).
Plasmids.
The plasmids cytomegalovirus (CMV)-RB
(14), pcDNA1-HA-p130 (48), and CMVp107-HA
(54) have been described previously. The TAg
expression vectors pSG5-T, pSG5-K1, pSG5-H42Q, pSG5-D44N, pSG5-HSJ1-T, and pSG5-HSJ1-HQ have been described previously (44, 51). The plasmids CMVT7DP1 (23) and CMVE2F-4-HA
(11) have been described previously. The luciferase reporter
plasmids 3xWT-E2F (24) and dihydrofolate reductase
(DHFR)-luc (pWTluc); the DHFR promoter with a mutant E2F site, pNWluc
(27, 40); and the E2F-1 promoter luciferase construct
containing two wild-type (pGL2-AN) or mutant E2F sites (
E2FA+B) have
been described previously (30). The CD19 expression vector
was kindly provided by T. Tedder (Duke University).
Antibodies.
Immunoprecipitations and Western blot analysis
were performed as described previously (45). The following
antibodies were used in this study: antihemagglutinin (HA), 12CA5
(Babco); anti-pRB, XZ77 (Santa Cruz) and 21C9 (a gift of David
Cobrinik); anti-adenovirus E1A, M73; rabbit anti-mouse immunoglobulin G
(Sigma); anti-p107, SD15 (Santa Cruz); anti-p130, C-20 (Santa Cruz);
and anti-CD19 (provided by J. Gibbon, Dana-Farber Cancer Institute).
Gel retardation analysis.
Extracts from transfected Saos-2
cells (see Fig. 5) were prepared by a minilysis procedure
(24). Extracts from MEFs expressing TAg (see Fig. 6) were
prepared as previously described (29, 51). The gel
retardation assays utilized an oligonucleotide probe that contained the
E2F binding site of the DHFR promoter (38, 51).
Immunoprecipitation-DOC release experiment.
Extracts were
prepared from confluent MEFs with TNN extraction buffer (50 mM Tris-HCl
[pH 7.5], 150 mM NaCl, 5 mM EDTA, 0.5% Nonidet P-40, 10 µg of
aprotinin per ml, 10 µg of leupeptin per ml, 0.1 mM
phenylmethylsulfonyl fluoride, 4 mM NaF, 0.1 mM Na orthovanadate)
(24) and incubated with either an irrelevant antibody
(rabbit anti-mouse immunoglobulin G and M73) or anti-p130 (C-20) and
protein A-Sepharose (Pharmacia). The immune complexes were washed four
times with NET-N (20 mM Tris-HCl [pH 8.0], 100 mM NaCl, 1 mM EDTA,
0.5% Nonidet P-40) and once with buffer A (20 mM HEPES [pH 7.5], 50 mM KCl, 1 mM MgCl2, 10% glycerol, 0.1% Nonidet P-40, 0.5 mM dithiothreitol), resuspended in 15 µl of buffer A containing 0.8%
deoxycholate (DOC), and eluted on ice for 15 min. The eluate (10 µl)
was treated with 15 µl of neutralization buffer (buffer A containing
1 mg of bovine serum albumin per ml, 0.1 µg of single-stranded DNA
per ml, 0.8% Nonidet P-40, and 6 mM MgCl2) before
incubation with the DHFR probe.
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RESULTS |
The J domain of TAg is required to relieve RB family-mediated
G1 arrest.
It has been reported that transfection of
plasmids expressing wild-type pRB, p107, or p130 in the osteosarcoma
cell line Saos-2 [Rb-1(/)], leads to an accumulation
of cells arrested in the G1 phase of the cell cycle
(4, 14, 33, 37, 48, 54). This G1 arrest requires
an intact RB pocket or TAg binding domain (13, 18). The
arrest can be overcome by expression of E1A or E2F (34, 35,
54).
We wished to determine whether the J domain of TAg was required to
overcome the G1 arrest induced by the RB family proteins. To address this, we assayed the ability of wild-type TAg and various TAg mutants to overcome the G1 arrest. The constructs are
shown schematically in Fig. 1. They are
wild-type TAg (T), an LXCXE mutant (K1) unable to bind to the RB
family proteins, two single-residue substitutions (H42Q and D44N)
within the conserved J domain HPD motif, a chimeric TAg (HSJ1-T) in
which the N-terminal J domain has been deleted and replaced with the J
domain from the human DnaJ homolog HSJ1, and, finally, the
single-residue HPD mutant (HSJ1-HQ) of HSJ1-T.
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FIG. 1.
Schematic representation of the TAg constructs used in
this study. The J domain is contained entirely within the first exon of
TAg (residues 1 to 82). The absolutely conserved HPD motif is indicated
(residues 42 to 44). Two mutants of the HPD motif were assayed: a
histidine-to glutamine substitution at residue 42 (H42Q) and a
glutamate-to-asparagine substitution at residue 44 (D44N). A mutant
containing a point mutation of the RB family-binding
LXCXE motif, glutamine 107-to-lysine (K1), was also
assayed. In the last two constructs, the first exon of TAg was deleted
and replaced with the J domain of a cellular protein. The shaded box
indicates the heterologous J domain from the human DnaJ homolog HSJ1
fused to residue 83 of TAg, resulting in the chimeric HSJ1-T protein.
In the final construct, the histidine-to-glutamine mutation in the HPD
domain was introduced into the chimeric HSJ1-T protein, resulting in
the mutant chimeric protein HSJ1-HQ (44).
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In the experiment shown in Fig.
2A,
transient expression of pRB in SaoS-2 cells resulted in a 21% increase
in the number of
cells in the G
1 phase relative to that in
the control vector (defined
as zero). There was a corresponding
decrease in the proportion
of cells in S phase (not shown).
Coexpression of wild-type TAg
could overcome the pRB-induced
G
1 arrest to a significant extent.
In contrast, the RB
binding domain mutant K1 did not override
the G
1 arrest.
This indicates that binding by TAg was necessary
for relief of the pRB
growth-suppressive activity.
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FIG. 2.
An intact LXCXE motif and J domain of TAg are
required to override a G1 arrest mediated by pRB, p107, and
p130. Saos-2 cells were transfected with a CD19 expression vector (1 µg), pCMV-RB (A [2 µg when alone and 0.5 µg when cotransfected
with T]), pCMV-p107HA (B [6 µg when alone and 2 µg when
cotransfected with T]), or pcDNA1-HA-p130 (C [8 µg when alone and 2 µg when cotransfected with T]) and the TAg constructs pSG5-T (6 µg), pSG5-K1 (6 µg), pSG5-H42Q (18 µg), pSG5-D44N (18 µg),
pSG5-HSJ1-T (6 µg), and pSG5-HSJ1-HQ (18 µg). Different amounts of
input DNA were used to obtain equal levels of expression of the
proteins. Cells were harvested 36 h posttransfection, stained for
CD19 and DNA content, and analyzed by flow cytometry (15).
The percent increase in G1 cells was calculated by
subtracting the value obtained with the CD19 vector alone. The
experiment was repeated three times, and the results from one
representative experiment are shown. The Western blot shown below each
graph was prepared with extracts from the experiment illustrated. The
blot was probed with an anti-TAg antibody, pAB101, and developed with
alkaline phosphatase-conjugated anti-mouse antibody and nitroblue
tetrazolium and 5-bromo-4-chloro-3-indolylphosphate toluidinium salt.
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To determine whether the J domain was also required to override
pRB-dependent G
1 arrest, several N-terminal mutant
constructs
were tested in this assay. The J domain mutants H42Q and
D44N
were unable to override the pRB-mediated growth repression (Fig.
2A), even though they retain the ability to bind to pRB (reference
44 and data not shown). Replacement of the
N-terminal 82 residues
of TAg with the J domain from a human DnaJ
homolog, HSJ1, restored
the ability of TAg to override the pRB-mediated
growth arrest.
The corresponding J domain mutant, HSJ1-HQ, was
defective. These
results demonstrate that an intact J domain of TAg is
required
to overcome a pRB-induced G
1 arrest.
In this experiment, the amount of input DNA was adjusted for each
construct to achieve equivalent levels of protein expression
as assayed
by Western blotting. As shown in the bottom panel of
Fig.
2A, the TAg
constructs were expressed at similar levels,
and hence the differences
in their ability to overcome a G
1 arrest
do not result from
variation in the level of expression. Furthermore,
we have previously
demonstrated by pulse-chase experiments that
the stabilities of the K1,
H42Q, and HSJ1-T proteins are similar
to that of wild-type TAg
(
44).
To determine whether the LXCXE and J domains of TAg were also
required to relieve a G
1 arrest induced by the two
RB-related
proteins p130 and p107 in Saos-2 cells, the same TAg
constructs
were cotransfected with expression plasmids for p130 or
p107.
As was the case for pRB, expression of p107 led to an increase
in
the percentage of cells in the G
1 phase of the cell cycle
(Fig.
2B). Expression of wild-type TAg or HSJ1-T was able to
significantly
override the p130-dependent G
1 arrest. In
contrast, neither the
LXCXE mutant K1 nor the J domain mutants
H42Q, D44N, and HSJ1-HQ
could override the p107-mediated G
1
arrest.
Finally, the ability of TAg to override a p130-dependent growth arrest
in Saos-2 cells was also dependent on intact LXCXE
and J domains of
TAg (Fig.
2C). These results suggest that both
the LXCXE and J
domains are required to overcome a G
1 arrest of
Saos-2
cells induced by members of the RB family. The expression
of the
various TAgs is shown in the bottom panels of Fig.
2B and
C.
The J domain of TAg is required to relieve pRB- and p130-dependent
repression of E2F activity.
The ability of RB family members to
induce a G1 arrest in Saos-2 cells has been correlated with
their ability to repress E2F transcriptional activity (33,
37). Based on the ability of TAg to override RB family-mediated
G1 arrest, it was not unreasonable to ask whether TAg could
also override RB family-dependent E2F repression and, if so, whether
the LXCXE and J domains were both required for this effect.
Initially, we tested the effect of expression of pRB in Saos-2 cells on
the activity of a luciferase reporter construct (3xWT-E2F)
that
contained three E2F binding sites and a TATA box (
24).
As
shown in Fig.
3A, expression of pRB
resulted in a threefold
decrease in the activity of 3xWT-E2F.
Coexpression of wild-type
TAg and HSJ1-T could partially override the
RB-mediated transcriptional
repression of this reporter. However,
neither the LXCXE mutant
K1 nor any of the J domain mutations could
override the pRB-dependent
repression of E2F activity. This
demonstrates that the partial
override observed with wild-type TAg
requires an intact J domain
as well as an intact LXCXE domain.
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FIG. 3.
Intact LXCXE and J domains of TAg are required to
override pRB- and p130-mediated repression of E2F activity.
Thirty-five-millimeter-diameter plates of Saos-2 cells were transfected
in three independent experiments with the reporter plasmids
3xWT-E2F-luciferase (A and B [0.5 µg]) and CMV- -galactosidase
and pCMVRB (A [40 ng]) or pcDNA1-HA-p130 (B [0.5 µg]) with the
TAg constructs pSG5-T (1.5 µg), pSG5-K1 (1.5 µg), pSG5-H42Q (4.5 µg), pSG5-D44N (4.5 µg), pSG5-HSJ1-T (1.5 µg), and pSG5-HSJ1-T HQ
(4.5 µg). Thirty-six hours after transfection, cells were extracted
in situ and assayed for luciferase activity and -galactosidase
activity to correct for transfection efficiency. Shown is the average
of three independently performed experiments ± standard
deviation.
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We next tested the ability of the pRB-related protein p130 to repress
E2F transcription from this promoter. As in the case
of pRB,
expression of p130 repressed the activity of 3xWT-E2F
in Saos-2 cells
(Fig.
3B). Furthermore, wild-type TAg and HSJ1-T
could
efficiently override the p130-mediated transcriptional repression.
The
override of p130-mediated repression appeared to be more complete
than
the override of pRB-mediated repression. The reasons for
this effect
are not clear. Similar to the effects seen in Fig.
3A, the LXCXE
mutant and each of the J domain mutants were unable
to override the
p130-mediated repression of the E2F reporter.
This again indicates a
requirement for both the LXCXE domain and
the J domain in
overcoming the transcriptional repression.
We wanted to assess the ability of TAg to override repression of E2F
transcriptional activity of a more physiologically relevant
promoter,
since the 3xWT-E2F construct used in the experiments
described above is
an artificial promoter. The promoters for DHFR
and E2F-1 contain
specific DNA binding sites for E2F as well as
several other
transcription factors. The reporter activity for
each of these
promoters increases several fold during the G
1/S-phase
transition, and this increase is dependent on the E2F sites (
27,
30,
40). For example, mutations in the single E2F binding
site in
the DHFR promoter or the two sites in the E2F-1 promoter
abrogated
their cell cycle-dependent increase in activity.
To test the effect of TAg on the DHFR and E2F-1 promoters, we repeated
the experiment described above with p130 to repress
the E2F activity
(Table
1). To determine the specific
effect
of TAg on E2F-dependent transcription, the activity of the
wild-type
promoters was compared to that obtained with the
corresponding
mutant promoters lacking functional E2F binding sites.
When p130
was expressed in Saos-2 cells, the activity of the wild-type
DHFR
promoter was repressed twofold relative to that of the mutant
form
(Fig.
4A and Table
1). Coexpression of
TAg could efficiently
override the repression, whereas coexpression of
the LXCXE mutant
K1 or the J domain mutants H42Q and D44N could
not.
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FIG. 4.
Intact LXCXE and J domains of TAg are required to
override p130-mediated repression of E2F activity on physiological
promoters. Wild-type (WT) DHFR-luc or mutant DHFR-luc reporter (A [0.5
µg]), wild-type E2F-1 (pGL2-AN) or mutant E2F-1-luciferase
(E2FA+B) (B [0.5 µg]), and CMV--galactosidase and
pcDNA1-HA-p130 (0.5 µg), with the TAg constructs pSG5-T (1.5 µg), pSG5-K1 (1.5 µg), pSG5-H42Q (4.5 µg), pSG5-D44N (4.5 µg),
pSG5-HSJ1-T (1.5 µg), and pSG5-HSJ1-T HQ (4.5 µg), were transfected
as described in the legend to Fig. 3. In panel A, the activity of the
wild-type DHFR promoter reporter was normalized to that of a reporter
containing a mutation in the E2F DNA binding sites. Similarly, in panel
B, the wild-type E2F-1 promoter reporter activity was normalized to
that obtained with the mutant reporter in the absence of p130. In each
panel, the average of three independent experiments is shown.
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Similar results were obtained with the E2F-1 promoter (Fig.
4B
and Table
1). Expression of p130 led to a threefold reduction
of the wild-type E2F-1 promoter (pGL2-AN) activity relative to
that of the mutant promoter (
E2FA+B). Coexpression of TAg could
efficiently override p130-mediated repression. However, coexpression
of
the LXCXE or J domain mutants had no effect. This is again
consistent with a requirement for an intact J domain to override
p130-mediated E2F repression.
The J domain of TAg is required to disrupt RB family-E2F DNA
binding complexes.
RB family proteins form DNA binding complexes
with the E2F family of transcription factors. We have previously
reported that expression of wild-type TAg, but not an LXCXE mutant
of TAg, could disrupt p130-E2F and p107-E2F DNA binding complexes
(51). Since the J domain was required to relieve pRB- and
p130-mediated E2F repression, we wanted to determine whether the J
domain of TAg was required for the disruption of p130-E2F DNA binding
complexes. To this end, we reproduced the p130-E2F DNA binding complex
by transfecting its components into Saos-2 cells. Protein complexes were extracted by a protocol that preserves E2F DNA binding activity from transfected proteins while virtually eliminating E2F DNA binding
activity from endogenous E2F complexes (24).
As shown in Fig.
5 (lane 2), expression
of E2F-4 with DP1 led to the formation of a specific DNA binding
complex. If p130
was coexpressed with E2F-4-DP1, then an additional DNA
binding
complex was observed (lane 3). In contrast, when TAg was
coexpressed,
the p130-E2F-4-DP1 complex was significantly reduced (lane
4).
Coexpression of the K1 mutant had no effect (lane 5). J domain
mutants of TAg retain the ability to efficiently associate with
p130
via the LXCXE motif (
45). Hence, we considered the
possibility
that these mutants may either disrupt p130-E2F DNA binding
complexes
or alternatively become part of the complex. However,
coexpression
of the J domain mutants H42Q (lane 6) and D44N (lane 7)
did not
disrupt the p130-E2F DNA binding complexes or change their
mobility.
When the extracts were incubated with a variety of anti-TAg
antibodies,
no change in mobility or disruption was observed in the
p130-E2F
complexes of these cells (data not shown). Therefore, despite
an intact LXCXE domain, the J domain mutations of TAg were unable
to inhibit the formation of p130-E2F DNA binding complexes.
Furthermore,
we have been unable to detect TAg in these complexes. The
experiment
in Fig.
5 indicates that an intact J domain is required to
disrupt
p130-E2F DNA binding complexes. This may provide a mechanistic
explanation for the inability of J domain mutants to override
p130-mediated repression of E2F activity (Fig.
3 and
4).
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FIG. 5.
Intact LXCXE motif and J domain of TAg are required
to disrupt p130-E2F DNA binding complexes. Saos-2 cells were
transfected with CMVE2F-4-HA (2 µg) and CMVT7DP1 (0.5 µg) (lanes 2 to 7), pcDNA1-HA-p130 (8 µg when alone [lane 3] and 2 µg when
cotransfected with a TAg construct [lanes 3 to 7]), and T, as shown
by the constructs pSG5-T (6 µg [lane 4]), pSG5-K1 (6 µg [lane
5]), pSG5-H42Q (18 µg [lane 6]), and pSG5-D44N (18 µg [lane
7]). Thirty-six hours after transfection, extracts were prepared by
the minilysis procedure (24), incubated with an
oligonucleotide containing the DHFR promoter, and separated in a
nondenaturing polyacrylamide gel.
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We have previously shown that stable expression of wild-type TAg, but
not the LXCXE mutant K1, in MEFs greatly reduces the
level of
endogenous p130-E2F and p107-E2F DNA binding complexes
(
51).
To determine whether an intact J domain was also required
to disrupt
endogenous E2F complexes, we prepared lysates from
MEFs that had been
established with various constructs of TAg
(
44). Extracts
were prepared from growth-arrested cultures that
had been confluent for
at least 2 days by using an extraction
procedure that preserves
endogenous E2F DNA binding complexes
(
38). As shown in Fig.
6A, a slower-migrating complex was
observed
in extracts prepared from confluent cultures expressing either
K1 (Fig.
6A, lane 2) or H42Q (lane 3). However, in extracts from
cells
expressing wild-type TAg or the HSJ1-T chimera (lanes 1
and 4), only
the faster-migrating free E2F was observed. This
experiment
demonstrates that an intact J domain is required to
disrupt endogenous
E2F DNA binding complexes. The specific DNA
binding activity of the
indicated complexes was determined by
competition with unlabeled
competitor DNA (data not shown). For
reasons presently unknown, there
reproducibly appeared to be less
free E2F DNA binding activity present
in extracts prepared from
cells that expressed the H42Q mutant (compare
levels of free E2F
in lanes 3 and 2).
View larger version (65K):
[in this window]
[in a new window]
|
FIG. 6.
Intact LXCXE motif and J domain are required to
disrupt endogenous E2F DNA binding complexes. Gel retardation assays
were performed with extracts prepared from confluent MEFs that stably
expressed either TAg, the LXCXE mutant K1, the J domain mutant
H42Q, or the chimeric protein HSJ1-T. (A) Extracts were incubated with
an oligonucleotide from the DHFR promoter as in Fig. 5. (B) The
complexes observed with extracts from cells expressing K1 or H42Q
(lanes 2 and 3 from panel A) were incubated with a panel of antibodies.
(C) Immunoprecipitation-DOC release of E2F DNA binding activity.
Extracts prepared from confluent MEFs were immunoprecipitated with the
control antibody M73 (anti-adenovirus E1A [lanes 1 to 4]) or with
anti-p130 antibody (lanes 5 to 8). Immune complexes were denatured and
then renatured as described in Materials and Methods and incubated with
the DHFR promoter as in Fig. 4.
|
|
To confirm that the slower-migrating complex observed in the K1- and
H42Q-expressing cell lines contained pRB family proteins,
antibody
supershift experiments were performed with the same extracts
used in
Fig.
6A. An anti-p130 antibody was able to supershift
the majority of
the slower-migrating complex in extracts prepared
from K1-expressing
cells (Fig.
6B, lane 2) and H42Q-expressing
cells (lane 8). An
anti-p107 antibody supershifted a fraction
of the complex, indicating
that the complex also contained some
p107 (lanes 3 and 9). An anti-pRB
antibody could also supershift
some of the slower-migrating complex
(lanes 4 and 10). Two control
antibodies, normal rabbit serum (NRS),
and M73, an antibody against
the adenovirus E1A protein, had no effect
on the E2F DNA binding
complexes (lanes 5, 6, 11, and 12). Hence, an
intact J domain
was required to disrupt endogenous E2F DNA binding
complexes of
all three pRB-related proteins in confluent MEFs.
As an independent assay of the ability of p130 and p107 to associate
with E2F in cells expressing TAg, we performed an
immunoprecipitation-DOC
release experiment (Fig.
6C) (
24).
Lysates prepared from confluent
cultures of MEFs were
immunoprecipitated with an anti-p130 antibody
or with a control
antibody. Immune complexes were denatured by
DOC, followed by
renaturation in the presence of Nonidet P-40.
The treated lysates were
then subjected to gel shift analysis
with the DHFR probe. When
immunoprecipitations of p130 were treated
in this manner, E2F activity
was only coprecipitated with p130
in MEFs that expressed K1 (Fig.
6C;
lane 6) or H42Q (lane 7).
In contrast, no E2F DNA binding activity was
immunoprecipitated
by the p130 antibody from MEFs expressing wild-type
TAg (lane
5) or HSJ1-T (lane 8). A control antibody did not precipitate
E2F DNA binding activity from any of the cell lines. This confirms
that
an intact J domain is required to dissociate p130-E2F complexes.
| |
DISCUSSION |
Several domains participate in TAg-mediated cellular
transformation, including the p53 binding domain, the LXCXE or
pRB-binding motif, and the N-terminal J domain. In the present study,
we determined that the N-terminal J domain cooperates with the
LXCXE motif to inactivate the growth-suppressive properties of pRB,
p107, and p130, as well as to inhibit the ability of pRB and p130 to
repress E2F-dependent transactivation. Furthermore, the J domain as
well as the LXCXE motif is required to disrupt RB family-E2F DNA
binding complexes. While an intact LXCXE domain was required for
each of these activities, it was not sufficient. There was an absolute requirement for an intact J domain as well. These results indicate that
while LXCXE serves as a binding motif, necessary for TAg interaction with each member of the RB family, inactivation of RB
family function requires the J domain as well.
The growth-inhibitory activity of pRB and p130 has been shown to
correlate with their ability to bind to members of the E2F family of
transcription factors and repress E2F-dependent promoters (25,
33). Results with p107 have not been as clear-cut, but E2F
binding is still likely to be important for growth inhibition in most
cell types (43, 53). Our results strengthen this hypothesis. We have not been able to separate genetically the ability of TAg to
override RB family-mediated growth arrest from its ability to derepress
E2F-dependent transcription. This suggests that the basis for the
requirement for the J domain in both assays is likely to be the
derepression of E2F-dependent genes. The J domain is also necessary for
inactivation of p130 and p107 during TAg-mediated transformation
(44). Given that p130 and p107 regulate a subset of
E2F-dependent genes (16), it will be interesting to know whether these genes are derepressed by TAg in a J domain-dependent manner.
While the biochemical mechanism leading to the derepression of
E2F-dependent genes is not yet fully understood, two possibilities, which are not mutually exclusive, deserve consideration. One
possibility, discussed further below, is that the J domain is necessary
in order for TAg to compete efficiently with E2F for binding to RB family proteins. Another possibility is that the role of the J domain
is to inactivate RB family members by perturbing the stability or
phosphorylation status of RB family proteins. We have previously shown
these activities to be absolutely J domain dependent. Furthermore, the
steady-state levels of endogenous p130 are lower in MEFs expressing wild-type TAg than in MEFs expressing J domain mutants of TAg (44).
Binding of the LXCXE motif of TAg to RB family proteins is not
sufficient for disruption of RB family-E2F complexes and inactivation of their growth-suppressive properties. This is reminiscent of the
adenovirus E1A oncoprotein, which also targets the RB family of
proteins. Like TAg, adenovirus E1A contains an LXCXE motif essential for binding to RB family proteins (49). A second
domain, contained within conserved region 1 (CR1), is also required to disrupt RB family-E2F complexes (7, 10). E1A containing a mutation in CR1 could associate with pRB-E2F and p107-E2F DNA binding
complexes, but was unable to disrupt them. In this case, the CR1 mutant
of E1A became part of the E2F DNA binding complexes (17).
There are two significant differences between E1A and TAg. First, there
is no homology between the J domain of TAg and CR1 of E1A
(8). In fact, E1A does not contain any region of homology to
the J domain of DnaJ proteins. Second, we have not been able to detect
the J domain mutants of TAg as components of RB family-E2F complexes.
This study, along with the work on E1A, suggests that there is more to
the oncoprotein-RB family protein interaction than simple binding of
the LXCXE motif of the viral oncoprotein to the RB family proteins.
It appears that in spite of the common LXCXE motif, the adenovirus
E1A and SV40 TAg viral oncoproteins have adopted different strategies
to mediate complete inactivation of the RB family proteins. The
detailed study of these mechanisms should provide a new insight in the
biology of the oncogenic proteins of DNA tumor viruses, as well as a
new understanding of the regulation of RB family members and
E2F-dependent transcription.
| |
ACKNOWLEDGMENTS |
This work was supported by Public Health Service grant CA-63113
from the National Cancer Institute and the Women's Cancers Program of
the Dana-Farber Cancer Institute.
J.Z. was supported in part by the Ministerio de Educación y
Ciencia of Spain. J.A.D. is a Scholar of the Leukemia Society of
America.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dana-Farber
Cancer Institute and Harvard Medical School, 44 Binney St., Boston, MA 02115. Phone: (617) 632-3825. Fax: (617) 632-4381. E-mail:
james_decaprio{at}dfci.harvard.edu.
Present address: Department of Biochemistry, University of Santiago
de Compostela, Santiago de Compostela, La Coruna 15705, Spain.
Present address: Millennium Pharmaceuticals, Cambridge, MA
02139.
| |
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Mol Cell Biol, March 1998, p. 1408-1415, Vol. 18, No. 3
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
