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J Virol, February 1998, p. 1138-1145, Vol. 72, No. 2
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Regulation of the Human Proliferating Cell Nuclear
Antigen Promoter by the Adenovirus E1A-Associated Protein
p107
Benjamin H.
Lee,1,2
Mingsong
Liu,1,
and
Michael B.
Mathews1,3,*
Cold Spring Harbor Laboratory, Cold Spring
Harbor, New York 11724-22081;
Department
of Molecular Genetics and Microbiology, State University of New
York at Stony Brook, Stony Brook, New York
117902; and
Department of Biochemistry
and Molecular Biology, New Jersey Medical School, University of
Medicine and Dentistry of New Jersey, Newark, New Jersey
071033
Received 23 June 1997/Accepted 5 November 1997
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ABSTRACT |
The adenovirus E1A 243R oncoprotein is capable of transactivating
the expression of the human proliferating cell nuclear antigen (PCNA)
promoter. Mutational analysis of the E1A 243R protein suggested that
both its p300/CBP- and p107-binding regions are required for optimal
induction of the PCNA promoter (C. Kannabiran, G. F. Morris, C. Labrie, and M. B. Mathews, J. Virol. 67:425-437, 1993). We
show that overexpression of p107 antagonizes the induction of PCNA by
E1A 243R in transient expression assays. This inhibition is largely
independent of p107's ability to interact with E1A 243R, because p107
mutants unable to bind to E1A 243R retain the ability to repress the
E1A-activated PCNA promoter. Electrophoretic mobility shift assays with
the PCNA promoter detected the presence of p107 in one of the major
DNA-protein complexes, EH1, formed with HeLa cell nuclear extracts.
Promoter mutations that disrupt the formation of complex EH1 abrogated
p107's ability to reverse E1A 243R-induced PCNA expression. The same
mutations characterize a sequence important for the binding of
transcription factor RFX1 (C. Labrie, G. F. Morris, and M. B. Mathews, Nucleic Acids Res. 23:3732-3741, 1995), implying that p107
antagonizes E1A 243R-induced PCNA expression through this RFX1-binding
site. Our data are suggestive of a novel cooperative mechanism for
transactivation of PCNA expression, in which E1A 243R relieves
transcriptional repression exerted by p107 on the promoter.
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INTRODUCTION |
The adenovirus E1A oncogene products
are multifunctional proteins which possess both transforming and
transactivating capabilities (6, 51, 55). Alternative
splicing of the E1A transcript produces at least five E1A mRNAs,
chiefly the 13S and 12S species (7, 11), which are
translated into proteins containing 289 and 243 amino acid residues,
respectively (referred to as E1A 289R and E1A 243R) (6, 44).
While the transforming functions of E1A map to regions common to the
289R and 243R proteins (60), the CR3 domain unique to the
289R species endows it with potent transactivation properties (6,
44, 51, 55).
Concomitant with its ability to induce DNA synthesis and mitosis in
quiescent cells (44, 54, 56), the adenovirus E1A gene can
activate the expression of the proliferating cell nuclear antigen
(PCNA), a highly conserved protein intimately involved in cellular DNA
synthesis (47, 66). As an integral component of the
eukaryotic DNA replication machinery, PCNA plays a crucial role in
normal cellular growth and differentiation. PCNA is believed to
function in a manner analogous to a sliding clamp to increase the
processivity of DNA synthesis as an auxiliary factor of DNA polymerase-
and is necessary for the replication of both leading- and lagging-strand DNA in an in vitro simian virus 40 replication system (9, 52, 53, 58, 59, 62). In vivo, PCNA is required
for growth and cell cycle progression in both yeast (4) and
mammalian cells (31, 40) and is found in quaternary
complexes containing cyclins, cyclin-dependent kinases (CDKs), and the
inhibitor p21 (63-65, 67). Although PCNA protein and mRNA
levels change relatively little in cycling human HeLa (45)
and Chinese hamster ovary (40) cells, they increase
dramatically upon stimulation of quiescent cells by mitogenic agents,
including serum and growth factors or during the course of viral
infection (1, 8, 31, 42, 66).
In light of its essential role in normal cell cycle regulation, the
induction of PCNA during the transformation of quiescent rodent cells
by adenovirus (66) represents an informative system for
studying the mechanisms underlying cellular transformation and
transactivation by the adenovirus E1A oncogene products. We previously demonstrated that activation of PCNA expression by the
E1A oncoproteins occurs at the transcriptional level through an
increase in PCNA promoter activity (46). Significantly, the PCNA promoter is induced equally well by the smaller E1A 243R protein
and by the larger E1A 289R species, indicating that the CR3 region is
dispensable for PCNA activation by E1A (47). Analysis of the
PCNA promoter revealed that its induction by E1A 243R occurs through a novel cis-acting PCNA E1A-responsive element
(PERE) which resides between nucleotides 
59 and 45 relative
to the transcriptional start site (35) and can confer
induction by the E1A 243R oncoprotein upon a normally E1A-unresponsive
heterologous promoter (48). The PERE contains a sequence
homologous to an activating transcription factor (ATF) motif
(5'-TGACGTCG-3') at its 3' end, and the ATF-1 and CREB
transcription factors have been shown to be major components of
PERE-protein complexes (35-37). In addition, we have shown
that RFX1, a ubiquitous transcription factor with both activation and
repression properties (33), binds to a site which overlaps
with the ATF-CREB consensus motif and extends to sequences immediately
downstream of the PERE (36).
Most of E1A's pleiotropic actions are mediated by its capacity to bind
and subvert the function of well-characterized and important cellular
regulatory proteins, including the retinoblastoma susceptibility gene
product, pRB; pRB-related proteins p107 and p130; and the
transcriptional coactivators p300 and CBP (the CREB-binding protein)
(2, 3, 5, 19, 20, 41, 43). Our recent investigation of the
role played by the p300/CBP coactivators in E1A-induced PCNA expression
supported a mechanism whereby E1A 243R can target and transactivate the
PCNA promoter via a CBP-CREB-PERE pathway (37). However,
results obtained with a panel of E1A mutants argued that E1A 243R
displays a functional redundancy in its capacity to activate the PCNA
promoter and most likely induces PCNA expression by multiple mechanisms
via interactions with more than one E1A-binding protein (32,
50). In particular, optimal activation of PCNA by E1A 243R
requires domains of E1A 243R that interact with both the cellular
transcriptional coactivators p300/CBP and the retinoblastoma-related
tumor suppressor protein p107 (32).
Here we set out to assess the role of the retinoblastoma-related tumor
suppressor protein p107 in transactivation of the PCNA promoter. First,
we examined the consequences of overexpressing p107 on PCNA promoter
activity in transient transfection assays. Our data indicate that p107
antagonizes the ability of E1A 243R to transactivate a
PCNA-chloramphenicol acetyltransferase (CAT) reporter gene and that
this inhibitory effect is independent of p107's ability to associate
with E1A 243R, but dependent on an RFX1-binding site contained in the
promoter. In addition, we detected an association between p107 and the
PCNA promoter, finding that RFX1 and p107 are present in the same
DNA-protein complex in a mobility shift assay. These results provide
direct evidence for the involvement of p107 in the regulation of the
PCNA promoter by E1A 243R and suggest novel transcriptional regulatory
roles for p107 in gene expression and growth control in normal cells.
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MATERIALS AND METHODS |
Plasmids.
Wild-type PCNA87 CAT and constructs 46/39,
ATF-BAM, 56GA, and 59/56 CAT were described previously (35,
46). Reporter plasmids 53GT and 44/40 PCNA-CAT contain
single or multiple mutations in the PCNA promoter and were created by
using an oligonucleotide-directed mutagenesis kit (Amersham,
Buckinghamshire, United Kingdom). 44/40 PCNA-CAT contains a 5-bp
clustered mutation (5'-CAACG-3'
5'-ATCGA-3') between sites 44 and
40 of the PCNA promoter, while 53GT PCNA-CAT contains a
single G-to-T point mutation at position 53 of the promoter. Plasmids
expressing the E1B 19-kDa protein (pCMV19K), 
-galactosidase
(pCMV-gal), E1A243R (pCMV12S), and a truncated form of E1A 243R
product (pCMV12S.FS, predicted to encode only the first 22 amino acids
of E1A 243R), under the control of the cytomegalovirus promoter have
been described previously (47). Plasmid pCH110
(25), which also expresses -galactosidase, was obtained
from M. Gilman (Ariad Pharmaceuticals), and constructs expressing
wild-type p107 (pCMV107) and p107DE (pCMV107DE) (68), a
mutant form of p107 which does not bind to E1A 243R, were generously provided by M. Ewen (Dana-Farber Cancer Institute). All plasmids were
purified by two cesium chloride gradient ultracentrifugations followed
by polyethylene glycol precipitation to remove low-molecular-weight RNA.
DNA probes.
PCNA promoter fragments (~150 bp) used as
electrophoretic mobility shift assay (EMSA) probes encompass
nucleotides from 87 to +62 relative to the transcription start site
of the human PCNA promoter. They include wild-type EH87, EH46/39,
EH44/40, and EHATF-BAM probes. Sequences of wild-type EH87 and
mutants EH46/39 and EHATF-BAM have been reported previously
(35, 36). DNA fragments EH44/40 and EH53GT contain the
mutations described in the corresponding 44/40 and 53GT PCNA-CAT
plasmids described above. All DNA fragments (wild type or mutant
derivatives) were prepared by digestion of wild-type PCNA87 CAT
plasmid or mutant reporter plasmids with EcoRI and
HindIII and were radiolabeled with
[
-32P]dATP (3,000 Ci/mmol) and cold deoxynucleoside
triphosphates with DNA polymerase I (Klenow fragment). Probes were
isolated by electrophoresis in native 6% polyacrylamide gels and
eluted from gel slices in oligonucleotide buffer (10 mM Tris [pH
8.0], 100 mM NaCl, 1 mM EDTA) containing 0.5% sodium dodecyl sulfate. After phenol extraction and ethanol precipitation, purified probes were
dissolved in oligonucleotide buffer.
EMSAs.
Nuclear extracts were prepared according to a
modified version of the Dignam procedure described previously (17,
36). EMSA was carried out as before (36). Typically,
assays were performed with a 20-µl reaction mixture containing 1×
EMSA buffer (12 mM HEPES [pH 7.6], 50 mM NaCl, 1 mM dithiothreitol,
5% [vol/vol] glycerol), 1.5 µg of poly(dI-dC)-poly(dI-dC) as
nonspecific DNA competitor, 5 µg of HeLa cell nuclear extract, and
20,000 cpm of DNA fragment probe. Incubations were conducted on ice for
15 min in the absence of probe, followed by incubation at 16°C for 15 min after addition of the probe. When indicated, antibody was added to
the binding reaction mixture at least 1 h prior to the addition of
probes, and the incubation was performed at 4°C. Protein-DNA complexes were resolved in 4.5% polyacrylamide (39:1
N,N'-methylenebisacrylamide)-0.25× Tris-borate-EDTA gels.
Antibodies.
Anti-RFX1 antibody was a generous gift from P. Hearing (SUNY
Stony Brook), and p107 (SD9), anti-p53 (D0-1), and
anti-ATF-1 (C41-5.1) monoclonal antibodies were obtained from Santa
Cruz Biotechnology, Inc.
Transfections.
Transient expression assays were performed in
duplicate in American Type Culture Collection HeLa cells (passages 6 to
13) as described previously (47). Briefly, cells at 40 to
50% confluence were transfected by the calcium phosphate
coprecipitation technique (61). Unless otherwise indicated,
each 6-cm-diameter plate received a total of 20 µg of DNA, including
10 µg of reporter construct, 0.5 µg of either pCMV12S or
pCMV12S.FS, 0.5 µg of pCMV19K, and 1 µg of pCMV-gal or pCH110 as
a control for transfection efficiency and salmon sperm carrier DNA. The
plasmid pCMV19K encodes the E1B 19-kDa protein, which stabilizes
transfected DNAs (28, 47) and was included to enhance the
level of transfected reporter plasmid and improve sensitivity. The
cells were washed twice with phosphate-buffered saline, and fresh
medium was added 16 h after the transfection. Cells were harvested
48 h after the transfection.
CAT and -galactosidase assays.
Cell extracts were
prepared by freezing and thawing cells in 0.25 M Tris-HCl (pH 8.0). CAT
assays were performed so that they yielded values within the linear
range of the assay. Usually, up to 50 µl of cell extract was added to
the 100-µl CAT assay reaction mixture. Thin-layer chromatograms were
quantified with a Betascan System (AMBIS, San Diego, Calif.), and CAT
activity was expressed as the percentage of chloramphenicol acetylated by 50 µl of cell extract incubated at 37°C for 1 h.
-Galactosidase assays were performed as described previously
(27). Reaction mixtures were incubated at 37°C, and
reactions were stopped by addition of 1 M
Na2CO3. -Galactosidase activity was
expressed as the optical density at 420 nm obtained with 50 µl of
extract incubated at 37°C for 1 h. All CAT assay results were
normalized to the levels of -galactosidase activity.
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RESULTS |
p107 antagonizes E1A 243R-transactivated PCNA promoter
activity.
Analysis of a panel of E1A 243R deletion and point
mutants for their abilities to activate PCNA promoter-directed reporter gene expression in HeLa cells suggested that E1A activates
transcription of the PCNA gene by multiple mechanisms and that of the
known E1A 243R-associated cellular proteins, p300/CBP and p107 are good candidates for mediating transactivation of the PCNA promoter by E1A
243R (32). The involvement of the p300/CBP pathway has recently been confirmed (37). To characterize the putative
role of p107 in PCNA gene expression, we began by examining the effects on basal and E1A 243R-induced PCNA levels of overexpression of p107 in
transient expression assays. While the overexpression of p107 (2 µg
of plasmid) in HeLa cells did not have any detectable effect on basal
transcription from the wild-type PCNA87 CAT reporter, E1A
243R-induced PCNA-CAT expression was significantly reduced compared to
reporter levels in the absence of overexpressed p107 at all
concentrations of cotransfected E1A 243R tested (from 0.1 to 2.5 µg
of E1A 12S plasmid) (Fig. 1). This
inhibitory effect of p107 on E1A-induced PCNA expression was confirmed
in reciprocal experiments with various concentrations of cotransfected
p107 plasmid. HeLa cells were cotransfected with increasing amounts of
p107 (from 0 to 6 µg), and a constant amount of wild-type E1A 12S
(0.5 µg) or a control plasmid, E1A 12S.FS (0.5 µg). Again, overexpression of p107 did not exert any detectable effect on basal
transcription levels from the PCNA87 CAT reporter construct, even at
the largest amounts of cotransfected p107 plasmid (Fig. 2). In the absence of transiently
expressed p107, the E1A 12S plasmid stimulated PCNA-CAT expression by
30- to 35-fold. However, overexpression of p107 dramatically reduced
E1A 243R's ability to stimulate PCNA-CAT levels to less than 10-fold
in a dose-dependent fashion (Fig. 2).
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FIG. 1.
p107 inhibits E1A 243R-induced PCNA-CAT activity.
PCNA87 CAT (10 µg) reporter was transfected into HeLa cells with
either pCMV12S.FS (0.5 µg) or increasing amounts of pCMV12S (E1A
243R) plasmid (0.1, 0.5, or 2.5 µg) and a constant amount (2 µg) of
wild-type pCMV107 expression plasmid. The results are the average of
two independent transfections performed in duplicate with standard
deviations indicated.
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FIG. 2.
p107 antagonizes E1A 243R-induced PCNA expression
independent of its E1A-binding ability. Wild-type (WT) PCNA87 CAT
plasmid reporter (10 µg) was cotransfected into HeLa cells with
either pCMV12S.FS as a control or pCMV12S (E1A 243R) and increasing
amounts (0, 2, 4, or 6 µg) of either wild-type pCMV107 or mutant
pCMV107DE expression plasmids. CAT activity was corrected for
-galactosidase activity generated from a cotransfected reporter
plasmid and expressed as the means ± the standard deviation
relative to the level of CAT activity obtained by cotransfection of
wild-type PCNA87 CAT with pCMV12S.FS. These data represent the means
of three independent transfections performed in duplicate.
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To determine whether the inhibitory effect of p107 was simply
attributable to squelching (the sequestration of E1A 243R by
p107 in an
inactive complex), we conducted similar experiments
with a p107 mutant
(p107DE) deficient in its capacity to bind
to the E1A protein. Like
wild-type p107 protein, expression of
p107DE (from 0 to 6 µg) had no
significant effect on basal PCNA-CAT
levels but inhibited the E1A 243R
transactivation of PCNA-CAT
levels in a dose-dependent manner, although
it was somewhat less
effective than wild-type p107 overexpression
(Fig.
2). This dose-dependent
inhibition of E1A 243R-induced
PCNA-CAT levels was also observed
with two other p107 mutants, p107EC
and p107F846 (
68), that
are deficient in binding to E1A 243R
(data not shown). Thus, p107
appears to exert an inhibitory effect on
E1A-transactivated PCNA
expression that is independent of its binding
to E1A 243R.
Association of p107 with the PCNA promoter in vitro.
The
reversal of E1A 243R-induced PCNA promoter activity by p107 in vivo
raised the possibility that p107 might associate with the promoter. We
previously used an EMSA to characterize the interaction of cellular
factors with the promoter (36). When the DNA probe (EH87),
containing wild-type PCNA promoter sequences from 87 to +62 relative
to the transcription initiation site, was incubated with HeLa cell
nuclear extract, five major DNA-protein complexes (EH1 to EH5) were
formed (36) (Fig. 3A, lanes 1 and 7). To determine whether any one of these DNA-protein complexes
contains p107, we performed an antibody interference experiment with an
antibody directed against the p107 cellular factor. Preincubation of
HeLa cell nuclear extracts with p107 monoclonal antibody SD9
specifically supershifted the EH1 complex (lane 5). The supershifted
band was more intense than the EH1 band in control lanes, suggesting
that the p107 antibody stabilizes the EH1 complex. None of the EH87 protein complexes was altered by an unrelated monoclonal antibody directed against p53 (lane 4), consistent with our previous observation that p53 binds to upstream PCNA promoter sequences not contained in the
EH87 probe (49). In contrast, a monoclonal antibody against the ATF-1 transcription factor previously shown to disrupt PCNA promoter-protein complexes (36) disrupted EH87 complexes EH3 and EH4 (lane 6), demonstrating the specificity of the p107 antibody for complex EH1. Although p107 associates with cyclin A and CDK2 in
vivo (10, 16, 22, 23), antibodies against these proteins did
not perturb any of the EMSA complexes (data not shown). These data
suggest that p107 is a component of complex EH1.
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FIG. 3.
EMSA complex EH1 contains both p107 and RFX1. (A) An
end-labeled PCNA promoter fragment from 87 to +62 relative to the
transcription initiation site (EH87) was incubated with 5 µg of HeLa
cell nuclear extract, and the protein-DNA complexes were resolved on a
4.5% native polyacrylamide gel. Extracts were incubated in the absence
(lanes 1 and 7) or the presence of antibodies () against either RFX1
(lane 3), p53 (lane 4), p107 (lane 5), or ATF-1 (lane 6). As a control,
nuclear extract was incubated with normal rabbit serum (NRS) (lane 2).
Complexes EH1 to EH5 are denoted in order of increasing mobility. (B)
Formation of complex EH1 depends on an intact RFX1 site. Probes derived
from the wild-type PCNA87 CAT construct (EH87) or from promoter
constructs harboring mutations from 50 to 47 (EH ATF-BAM), 46 to
39 (EH 46/39), 44 to 44 (EH 44/40), or a G-to-T point
mutation at position 53 (EH 53GT) were incubated with HeLa nuclear
extract (5 µg), and the protein-DNA complexes were resolved in a
native gel.
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Complex EH1 formation is dependent on RFX1-binding site sequences
and contains RFX1.
Previous studies led us to suspect that
nucleotide sequences important for the formation of EH1 are also
essential for the binding of the transcription factor RFX1 to the PCNA
promoter (36). This idea was strengthened by the results of
EMSA with EH probes containing mutations within the RFX1-binding site,
namely EH46/39, EH ATF-BAM, and EH44/40. As shown in Fig. 3B,
the formation of complex EH1 was reduced in all cases (Fig. 3B, lanes 2 to 4). These results indicated that sequences between 50 and 40 are
important for EH1 complex formation. Moreover, a mutation further
upstream (EH53GT) that enhances the binding of RFX1 (39a) increased
the formation of the EH1 complex (lane 5). To determine directly
whether RFX1 is a component of complex EH1, HeLa cell nuclear extract
was preincubated with an antibody raised against RFX1. The RFX1
antibody specifically affected complex EH1 (Fig. 3A, lane 3), either
causing a weak supershift or abrogating the band, whereas normal
rabbit serum had no effect (Fig. 3A, lane 2). These data show that EH1
is a multiprotein complex, containing both the RFX1 transcription
factor and p107.
Inhibition of E1A 243R-transactivated PCNA expression requires an
intact RFX1 site.
Since p107 and RFX1 are components of complex
EH1 and EH1 formation is dependent upon sequences that are important
for RFX1 binding, it seemed possible that p107 inhibition might be
effected via the RFX1 site. We therefore determined whether p107
overexpression can reverse the E1A 243R-induced expression from the
PCNA promoter containing mutations in the RFX1-binding site. HeLa cells
were cotransfected with either wild-type PCNA87 CAT or 44/40 CAT and increasing amounts of p107 to assess the effect of this promoter mutation on the inhibitory action of overexpressed p107. The 44/40 mutation increased basal transcription levels slightly compared to
those of the wild-type promoter, but overexpression of p107 had no
significant effect on basal expression in either case. As in Fig. 1 and
2, p107 overexpression greatly reduced E1A 243R-induced PCNA-CAT levels
from those of wild-type PCNA87 CAT (Fig.
4), but was much less inhibitory with the
44/40 CAT reporter (Fig. 4). To eliminate confounding effects of
squelching, we repeated this experiment with the mutant p107DE protein.
The results of Fig. 5 show that p107DE
behaved similarly to wild-type p107 in that it antagonized E1A
243R-transactivated PCNA-CAT levels with the 44/40 promoter
mutation only weakly compared to the wild-type promoter. Thus, the
44/40 promoter mutation significantly relieves the inhibition of
E1A-induced transactivation by p107.
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FIG. 4.
p107 inhibition of E1A 243R-induced PCNA expression is
dependent on the RFX1-binding site. HeLa cells were transfected with
either wild-type PCNA87 CAT or 44/40 CAT reporter plasmid (10 µg), pCMV12S.FS or pCMV12S, and increasing amounts of pCMV107 (0, 2, or 4 µg) or pCMV107DE (0, 2, 4, or 6 µg) expression plasmid. CAT
activity was calculated as described in the legend to Fig. 1 and
represents the average of three independent experiments performed in
duplicate with standard deviations indicated.
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FIG. 5.
Inhibition of E1A-induced PCNA activity by p107DE is
also dependent upon RFX1-binding site sequences. HeLa cells were
transfected with either wild-type (WT) PCNA87 CAT or 44/40 CAT
reporter plasmid (10 µg), pCMV12S.FS or pCMV12S, and increasing
amounts of pCMV107DE (0, 2, 4, or 6 µg) expression plasmid. CAT
activity was calculated as described in the legend to Fig. 1 and
represents the average of three independent experiments performed in
duplicate with standard deviations indicated.
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We extended these experiments to further promoter mutants to determine
whether reversal of E1A 243R-induced transactivation
by p107 requires
an intact RFX1 site. The
44/
40 and
46/
39
mutations, which both
adversely affect RFX1 binding and EH1 complex
formation in vitro
(
36) (Fig.
3B), eliminated the ability of
p107 to antagonize
E1A 243R transactivation of the PCNA promoter
(Fig.
6). In contrast, p107 could still
reverse E1A 243R-induced
expression directed by PCNA promoters
containing mutations
53GT
and
56GA. These point mutations lie
within the PERE and reduce
transactivation by E1A 243R but reside
outside the RFX1-binding
site and do not adversely affect RFX1 binding
and EH1 complex
formation in vitro (Fig.
3B, lane 5) (
39a).
These data support
the conclusion that the repressive effect of p107 on
E1A-activated
PCNA expression is exerted through PCNA promoter
sequences which
constitute part of an RFX1 consensus binding site.
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FIG. 6.
Mutations that specifically affect the RFX1-binding site
abrogate reversal of E1A 243R-induced PCNA expression by p107.
Wild-type (WT) and mutant (44/40, 46/39, 53GT, 56GA CAT)
PCNA-CAT reporter constructs (10 µg) were cotransfected with either
0.5 µg of pCMV12S.FS (control) or pCMV12S (E1A 243R) and with or
without pCMV107 expression plasmid (2 µg). The fold increase ± standard deviation in CAT expression was normalized for
-galactosidase activity and represents the average of three
independent experiments done in duplicate.
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DISCUSSION |
p107 is a member of the pocket family of proteins that includes
the retinoblastoma tumor suppressor pRB and the p130 protein (15,
18, 21, 26, 29, 30, 39). Overexpression of p107 arrests cells in
the G1 phase of the cell cycle (12, 68), suggesting that it plays an important role in cell cycle progression. Because p107 is a nuclear phosphoprotein that can bind to and modulate
the activity of transcription factors, including E2F (16, 22,
38), one of its biological functions likely involves the
transcriptional regulation of genes involved in the control of cell
proliferation. Therefore, the downregulation of PCNA expression by p107
may constitute one of the pathways by which this E1A-associated protein
can influence the cell cycle.
In addition to the well-characterized regulatory mechanism mediated by
E2F (16, 22, 38), p107 can also repress transcription independently of its ability to interact with the E2F family of transcription factors (13). In fact, p107 has also been
shown to bind to and inhibit the transactivation domain of the
c-myc transcription factor (24). However, we did
not observe any effect of E2F overexpression in transient
expression assays with the minimal PCNA E1A-responsive promoter
(data not shown). The lack of clearly defined E2F or c-myc
binding sites in the minimal PCNA E1A-responsive promoter, and the
failure to detect E2F in PCNA promoter mobility shift assays by either
oligonucleotide competition or antibody interference (data not shown),
also argued that antagonism of E1A-induced PCNA expression by p107
occurs via a novel inhibitory mechanism. This reversal of E1A-induced
PCNA expression by p107 is congruous with p107's known transcriptional
repression properties. While p107 overexpression has no significant
effect on basal transcription from the PCNA promoter, it antagonizes
dramatically the transactivation of the PCNA promoter by E1A 243R.
Since p107DE and other derivatives which cannot bind E1A 243R retain
the ability to antagonize E1A 243R-induced promoter expression,
only a minor portion of this inhibition occurs via a squelching
mechanism. Evidently, p107's ability to reverse E1A
243R-transactivated PCNA expression resides in domains outside its
pocket region.
Antibody interference experiments demonstrated that the
retinoblastoma-related protein p107 and RFX1 participate in the same DNA-protein complex in vitro, but the existence and nature of any
physical or functional interaction between the two proteins remain to
be determined. Moreover, in contrast to the clear-cut effects of p107
overexpression, in vivo assays with RFX1 have been inconclusive to
date. RFX1 overexpression nonspecifically increased both basal and
E1A-transactivated PCNA promoter activity as well as the expression of
-galactosidase from control plasmids, so no firm conclusions could
be drawn (data not shown). Nevertheless, mutations that abolish the
RFX1-binding site and adversely affect the formation of complex EH1
abrogated the ability of p107 to reverse E1A-induced PCNA promoter
activity, suggesting that the inhibition by p107 requires these
cis-acting sequences. Taken together, these results argue
that p107 associates with the human PCNA promoter via the RFX1-binding
site (through some as yet uncharacterized protein-protein interaction
with RFX1 or another factor) to reverse E1A 243R transactivation of
PCNA. In support of this notion, p107 can act as a general
transcriptional repressor protein when tethered to DNA either as a GAL4
fusion protein or by virtue of its capacity to bind to E2F
(57). Thus, it is possible that p107 can interfere with the
function of one or several of the components of the basal transcription
machinery (57). Our findings with the PCNA promoter imply
that the p107-sensitive step is rate limiting for E1A-activated transcription, but not for basal transcription, at least in HeLa cells.
Although it is possible that the human papillomavirus E7 protein (which
is present in these cells and can also bind p107) participates in the
regulation of the PCNA promoter, no significant effects have been
detected in transfection experiments carried out to date (not shown).
Recently, we demonstrated that E1A 243R can target and transactivate
the PCNA promoter through interactions of the PERE with the cellular
coactivator protein CBP and CREB (37). In view of
complementation studies with different E1A mutants suggesting the
existence of functional domains within E1A that simultaneously associate with both p107 and p300/CBP to optimally transactivate PCNA
expression (32), we propose that transactivation of the PCNA
promoter by E1A occurs via a multistep mechanism (Fig.
7). According to this model, E1A 243R
initially targets the PERE via a CBP-CREB-DNA interaction (Fig. 7A).
The E1A 243R-CBP interaction by itself may suffice to stimulate the
PCNA promoter (Fig. 7B), because CBP is known to interact with
components of the basal transcription machinery, in particular, TFIIB
(14, 34). Once targeted to the promoter, however, E1A 243R
may exert additional effects which contribute to PCNA activation: as
illustrated in Fig. 7C, E1A 243R may simultaneously interact with
p107, either directly or indirectly, to mediate the relief of
transcriptional repression exerted by p107 on the PCNA promoter.
View larger version (24K):
[in this window]
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|
FIG. 7.
Model for activation of the human PCNA promoter by E1A
243R. Schematic diagram of the minimal PCNA-E1A-responsive promoter is
illustrated with the cis-acting PERE boxed in gray, the
RFX1-binding site, and the cellular factors indicated. A possible
mechanism by which E1A 243R might transactivate the PCNA promoter is
depicted sequentially. (A) E1A 243R first targets the PCNA promoter at
the PERE site via a CBP-CREB-PERE pathway (37). (B) The
binding between E1A and CBP activates the promoter by itself through an
interaction between CBP and components of the general transcription
machinery (general transcription factors [GTFs]). (C) E1A 243R
increases PCNA promoter expression by mediating the relief of a
transcriptional repression exerted on the promoter by p107. Note that
the events depicted in panels B and C might take place
simultaneously.
|
|
This model provides a link between the p107 protein and the human PCNA
promoter, a relationship which had previously been inferred only from
mutational studies of E1A 243R and correlation with the known
E1A-binding proteins (32). It readily explains the
observations reported here which implicate p107 in the activation of
PCNA by E1A. Presumably, E1A 243R that is transfected into cells
relieves transcriptional repression of the PCNA promoter mediated by
endogenous p107 present in these cells. When p107 is overexpressed,
however, the amounts of E1A present in the cell are insufficient to
wholly overcome the inhibition and relieve the repression (Fig. 1 and
2). Therefore, overexpression of p107 appears to antagonize the
capacity of E1A to transactivate the PCNA promoter in these transient
expression assays. Furthermore, the coordinate action of E1A 243R
mediated via p300/CBP and p107 at the PCNA promoter (Fig. 7C) can
account for observations implying that the p300/CBP and p107 binding
regions have to be on the same E1A protein molecule for full activation
of the PCNA promoter by E1A 243R (32). This synergy between
p107 and p300/CBP in the regulation of PCNA gene expression sheds new
light on the pathways and networks of interactions which control the
cell cycle and normal cellular growth.
| |
ACKNOWLEDGMENTS |
B.H.L. and M.L. contributed equally to this work.
We thank P. Wendel for excellent technical assistance. We are grateful
to P. Hearing for RFX1 reagents and M. Ewen for p107 expression
plasmids and to C. Labrie for helpful discussions and contributions at
the initial stages of this study.
This work was supported by National Institutes of Health grant CA
13106.
| |
FOOTNOTES |
*
Corresponding author. Present address: Department of
Biochemistry and Molecular Biology, New Jersey Medical School,
UMDNJNewark, 185 S. Orange Ave., Newark, NJ 07103-2714. Phone: (973)
972-4411. Fax: (973) 972-5594. E-mail: mathews{at}umdnj.edu.
Present address: Cardiovascular Research Institute, University of
CaliforniaSan Francisco, San Francisco, CA 94143-0130.
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Abstract
Introduction
