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Molecular and Cellular Biology, October 2001, p. 7105-7114, Vol. 21, No. 20
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.20.7105-7114.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
The Modified Human DNA Repair Enzyme
O6-Methylguanine-DNA Methyltransferase Is a
Negative Regulator of Estrogen Receptor-Mediated Transcription
upon Alkylation DNA Damage
Alvin K. C.
Teo,
Hue
Kian
Oh,
Rahmen B.
Ali, and
Benjamin F. L.
Li*
Chemical Carcinogenesis Laboratory, Institute
of Molecular and Cell Biology, National University of Singapore,
Singapore 117609, Republic of Singapore
Received 22 March 2001/Returned for modification 25 April
2001/Accepted 16 July 2001
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ABSTRACT |
Cell proliferation requires precise control to prevent mutations
from replication of (unrepaired) damaged DNA in cells exposed spontaneously to mutagens. Here we show that the modified human DNA
repair enzyme O6-methylguanine-DNA
methyltransferase (R-MGMT), formed from the suicidal repair of the
mutagenic O6-alkylguanine (6RG) lesions by MGMT
in the cells exposed to alkylating carcinogens, functions in such
control by preventing the estrogen receptor (ER) from transcription
activation that mediates cell proliferation. This function is in
contrast to the phosphotriester repair domain of bacterial ADA protein,
which acts merely as a transcription activator for its own synthesis
upon repair of phosphotriester lesions. First, MGMT, which is
constitutively present at active transcription sites, coprecipitates
with the transcription integrator CREB-binding protein CBP/p300
but not R-MGMT. Second, R-MGMT, which adopts an altered conformation,
utilizes its exposed VLWKLLKVV peptide domain (codons
98 to 106) to bind ER. This binding blocks ER from association with the
LXXLL motif of its coactivator, steroid receptor coactivator-1, and
thus represses ER effectively from carrying out transcription that
regulates cell growth. Thus, through a change in conformation upon
repair of the 6RG lesion, MGMT switches from a DNA repair factor to a
transcription regulator (R-MGMT), enabling the cell to sense as well as
respond to mutagens. These results have implications in chemotherapy
and provide insights into the mechanisms for linking transcription
suppression with transcription-coupled DNA repair.
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INTRODUCTION |
Exposure to environmental mutagens,
such as UV irradiation and N-nitroso compounds, accounts for
80% of the human cancer incidence (30). The effectiveness
of our cells' attempts to repair the DNA lesions inflicted by mutagens
on our DNA before DNA replication is fundamentally linked to
manifestation of the disease through this etiological pathway.
The p53 protein is critical here for maintaining genomic integrity,
since its induction upon DNA damage enables the cell to acquire
sufficient time to repair the damaged DNA by halting cell cycle
progression through its effector, the cell cycle-dependent kinase
inhibitor p21WAFI (11, 15). However, p53
appears to be only a downstream effector of this DNA damage response
pathway in the cell, since cellular factors, such as the hChk1
and hChk2 (human homologs of the yeast RAD53 and CDS1 proteins), are
shown to stabilize p53 through phosphorylation upon exposure to
mutagens (6, 14, 35). While much is known about cell
regulation where external stimuli are transduced via the membrane
receptors and kinase cascades to activate the nuclear DNA
(8), knowledge of reciprocal pathways through which
DNA, when it is damaged, signals cellular response through immediate factors remains circumstantial.
The high-fidelity property of DNA and RNA polymerases enables them to
serve as important signaling factors for the integrity of the DNA as
they are arrested at the bulky DNA lesions inflicted by mutagens
(33) while processing along the DNA to carry out their
functions. However, what could be an effective signaling factor for the
DNA containing subtle DNA lesions that do not arrest the polymerases?
DNA repair enzymes are molecular sensors of damaged DNA in the cell,
since they recognize and repair damaged DNA. It would be a very
effective survival strategy if the same DNA repair enzyme could
also be a signaling molecule as well as a regulator for the presence of
damaged DNA in the cells. The Escherichia coli ADA protein
is a unique example, exhibiting these properties in protecting the
bacteria from the cytotoxic effects of the phosphotriester lesions in
the DNA that are induced by alkylating agents. Upon repairing the
phosphotriester lesions by transferring the alkyl group from the
phosphotriester lesion to the active site of the phosphotriester repair
domain at its N terminus, the alkylated protein becomes a transcription
activator for its own synthesis. This increases the amount of the ADA
protein in the bacterial cell for protection against further damage
from alkylating agents (38, 39). Unfortunately, such an
elegant DNA repair and response pathway appears to be limited to the
prokaryotes, since homologs of the ADA protein are not found in the
eukaryotes (44).
Nevertheless, the O6-methylguanine-DNA
methyltransferase (MGMT), which has an alkyl transfer repair
mechanism similar to that of the E. coli ADA protein, is
present in all organisms. It protects cells from the mutagenic and
cytotoxic effects of alkylating carcinogens (10) by
transferring the alkyl group of O6-alkylguanine
(6RG) formed in the DNA by alkylating carcinogens (20) to
the cysteine residue at its active site (28, 29). This
repair mechanism, however, depletes instantly the MGMT activity in the
cell as MGMT is converted to the active-site alkylated and inactive
MGMT, R-MGMT (19). Even though the presence of unrepaired
6RG lesions in the cellular DNA is detrimental, producing point
mutations upon DNA replication (1) or mutated mRNA that can be instantly translated into an altered protein (42)
upon transcription (12), the MGMT suicidal repair is
preserved through evolution (28, 29). Could R-MGMT serve
as a unique molecular memory of exposure to alkylating carcinogens
(3), similar to the alkylated ADA protein in bacteria, and
therefore provide some important cellular functions?
Several observations suggested that human MGMT and R-MGMT could
regulate estrogen receptor (ER)-dependent activities. First, the
ligand-bound nuclear receptor activates cell proliferation (31,
37), and therefore, its activity must be controlled upon DNA
damage. Second, active MGMT localizes at the active transcription sites
of RNA polymerase II-dependent genes (2) (including
ER-regulated genes). Third, biochemical analyses show that human R-MGMT
adopts an altered conformation in exposing the VLWKLLKVV
domain (26) containing an LXXLL motif that also is
found in transcription coactivators for their binding to nuclear
receptors (13). Fourth, the LXXLL motifs of R-MGMT and the
coactivator glucocorticoid receptor interacting protein binding to the
ligand binding domain of ER-
adopt similar amphipathic
-helix structures (7, 34). Finally, this LXXLL motif of
human and mammalian MGMTs is not found in lower organisms that do not
have ER.
Here we provide the experimental findings of how human R-MGMT serves as
a DNA damage-induced transcription suppressor for regulating
ER-mediated cell proliferation upon exposure to alkylating agents.
These findings serve as an important example of how a DNA repair enzyme
interplays with transcription factors and integrators to
regulate cell proliferation upon DNA damage, and they provide a good
reason for the suicidal repair of the 6RG lesions by MGMT to form
R-MGMT. This appears to be a highly specific protein modification in
the cell that enables the DNA to regulate itself upon alkylation damage
by transducing the signal from the 6RG lesions in the damaged DNA via
R-MGMT to block ER from activating the DNA directly to transcribe or
indirectly to replicate by ER-transcribed gene products.
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MATERIALS AND METHODS |
Cell extracts and drug treatments.
Cells were from the
American Type Culture Collection. Nuclear and total cell extracts were
prepared as described previously (3, 19), with added
cocktail protease inhibitors (1:500; Sigma) and 0.1% Triton (required
for ER extraction, though it causes minor cleavage of MGMT by V8; see
Fig. 2C and F). Cdex media were made from serum treated with
charcoal-coated dextran (Hyclone) and RPMI medium (Gibco) without
phenol red. Stock solutions of O6-benzylguanine
(6BG) (200 µM) and iodomethane (MeI) (10 mM) were made in serum-free
medium, and a solution of 17-
estradiol (E2) (Sigma) was made
in ethanol. For experiments with Cdex medium, cells were first grown in
normal medium to 60% confluence. After washing with phosphate-buffered
saline (PBS), they were grown in Cdex medium for 48 h and replaced
with fresh Cdex medium before experiments with E2.
Immunochemistry.
The Mab.677-F11 monoclonal antibody to
steroid receptor coactivator 1 (SRC-1) was a gift from B. W. O'Malley. Antibodies for CBP/p300 (rabbit polyclonal Pab.451), ER-
(Pab.HC20, Pab.H184, and Mab.F10) and SRC-1 (goat Pab.N19 and Pab.M20)
were from Santa Cruz. Mab.CBP/p300 (Power Clone) was from Upstate. They
were used at a concentration of 2 µg/ml. For immunoprecipitation,
antibodies (2 µg of each) were added to the nuclear extracts (800 µg by Lowry assay) in buffer A (1 ml containing 150 mM NaCl, 50 mM
Tris [pH 8.0], 1 mM dithiothreitol, and 1 mM EDTA). After
incubation for 12 h at 4°C followed by centrifugation
(2,000 × g for 2 min), the supernatants were
transferred to respective anti-immunoglobulin (Ig) agarose beads
(20 µl of a 50% suspension; Sigma) for 2 h with gentle rolling.
Following washing with buffer A (three times; 1 ml), the
proteins were debound from the beads by boiling them in Laemmli buffer
(30 µl) for sodium dodecyl sulfate-polyacrylamide gel electrophoresis
and immunoblot analysis.
Flow cytometry.
A Becton Dickinson FACScan machine was used
to acquire and analyze 50,000 events (using Cellquest and Modfit). DNA
analysis was carried out by propidium iodide (PI) staining (50 µg/ml
at 20°C, 30 min) of ethanol (80%; 12 h at 
20°C)-fixed cells
digested with RNase (20 µg/ml for 30 min). For dual analysis of
expressed MGMT and DNA, cells transfected with wild-type (wt) and K107L MGMT cDNAs (19) were fixed in 1% paraformaldehyde (30 min
on ice) followed by permeabilization with 0.2% Tween 20 and blocking with 10% sheep serum (20°C for 30 min for both steps). Mab.3B8 (100 µl of a 3 µg/ml concentration in buffer C [1% Tween 20 and 10%
sheep serum in PBS]) was added to the cells (1 h at 37°C) followed
by washing two times with PBS (500 µl). After treatment with
fluorescein isothiocyanate anti-mouse Igs (200 µl of 1:50 dilution in
buffer C) for 30 min at 37°C followed by washing with PBS, the cells
were further processed for PI staining as described above.
In vitro binding.
GST-(wt) and MGMT (K107L) were
prepared as described previously (26). Recombinant ER-
(50 ng; Oncogene Science) was added to buffer B (100 µl of 50 mM
HEPES [pH 7.3], 0.1% Triton X, 10% glycerol, 100 mM KCl, and 1 mM
dithiothreitol) with glutathione-Sepharose (20 µl of a 50%
suspension)-bound fusion proteins (~100 ng) which were first treated
with bovine serum albumin (100 µl of 20% bovine serum albumin in
buffer B) at 4°C for 1 h. After shaking at 4°C for 15 min, the
beads were recovered and washed three times with 500 µl of
buffer B before boiling in Laemmli buffer for immunoblot analysis. In
peptide competition assays, high-pressure liquid chromatography-purified peptides (7 µg from a 1-mg/ml stock solution in argon-treated water; Research Genetics) were added to the
recombinant ER- for 10 min before binding.
ERE reporter and mammalian two-hybrid assays.
The
manufacturer's protocols (Qiagen) for transfection with Superfect were
followed. The luciferase estrogen-responsive element (ERE) and ER
reporter assay was described previously (23). First, the
human ER- cDNA was cloned into the pXJ41 vector similar to the
full-length wt and mutant MGMT DNAs (19). For the
mammalian two-hybrid assay (kit from Clontech), the cDNAs of Wt-MGMT,
K107L-MGMT, and the nuclear receptor binding domain of SRC-1 (NR) were
cloned into the V vector (with the VP-16 insert), whereas the ER cDNA was cloned into the M vector (with the GAL4 DNA insert). Besides the M
and V vectors (1 µg of each), pCMV-gal (0.5 µg as an internal control) and 5× Gal4luc3 (1 µg as the luciferase reporter) were cotranfected to the ER
MGMT+ HeLa CCL2
cells grown on 6-well plates in Cdex medium for 24 h and
stimulated with E2 (100 nM) for 24 h. For experiments with 6BG,
the ER MGMT SV40-virus-transformed human
MRC5 fibroblast (MRC5.SV40) cells were used, and the drug (25 µM) was added together with E2. The luciferase activities were
normalized to beta-galactosidase (-Gal) activities from triplicate experiments.
Labeling of RNA by [3H]uridine and RT-PCR analysis
of mRNAs.
Cells were grown in six-well culture dishes and labeled
with 50 µCi of [5,6-3H]uridine (Amersham, Little
Chalfont, England) for 6 h. Total RNA was isolated using the
Qiagen (Hilden, Germany) RNeasy-Kit. Two micrograms of the labeled RNAs
were either subjected to scintillation counting or resolved on a 1%
agarose gel for analyzing RNA. The resolved labeled RNAs were then
transferred to a nitrocellulose membrane. The filter was then air dried
and cross-linked with UV for 2 min. The amplifier-treated filter was
autoradiographed for 48 h. For reverse transcription PCR (RT-PCR)
(21) (kit from Promega), mRNA (2 µg) was reverse
transcribed with d(T)17 (0.5 µg) followed by PCR with
primers (0.05 µg of each) for -actin (5'-AGCGGGAAATGCTGCGTG-3' and
5'-CAGGGTACATGGTGGTGCC-3'), porphobilinogen deaminase (PBGD)
(5'-TCTGGTAACGGCAATGCGGC-3' and
5'-CCAGGGCATGTTCAAGCTCC-3'), progesterone receptor (PR)
(5'-GATTCAGAAGCCAGCCAGAG-3' and
5'-TGCCTCTCGCCTAGTTGATT-3'), and pS2
(5'-GGAGAACAAGGTGATCTGCG-3' and
5'-CACACTCCTCTTCTGGAGGG) under the following conditions: 5 min at 94°C, 30 cycles of 30 s at 94°C, 30 s at 60°C,
and 45 s at 72°C, and a final elongation of 5 min at 72°C. PCR
products were analyzed on a 1.8% agarose gel.
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RESULTS |
6BG inhibits the growth of breast cells expressing ER and MGMT
(mer+).
To investigate human R-MGMT
function, we treated some MGMT-positive (mer+)
and -deficient (mer) cells with 6BG, which
alkylates selectively the cysteine C145 residue of human MGMT without
causing DNA damage (26). Flow cytometry (FC) analysis of
these 6BG-treated cells in Fig. 1A shows
that the populations of S-phase cells decreased significantly (i.e.,
growth retardation) in the MCF7 and T47D breast cell lines expressing
MGMT (see the immunoblot in Fig. 1B), ER (Fig. 1C), and SRC-1 (Fig. 1D)
but not the pairs of mer+ (BT549) and
mer (MDA-231) ER-negative breast cells and
mer+ (HeLa CCL2) and
mer (MRC5.SV40) virus-infected cells. While
the levels of ER and SRC-1 proteins were not themselves affected by
6BG, the majority of MGMT in 6BG-treated mer+
cells was cleaved by protease V8 into the 14- and 18-kDa polypeptides, the fingerprint of R-MGMT (3, 36) (Fig. 1B, bottom panel).
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FIG. 1.
6BG inhibits the growth of breast cells expressing ER
and MGMT (mer+). (A) Flow cytometry analysis of
breast (MCF7 [panel 1], T47D [panel 2], BT549 [panel 3], and
MDA-231 [panel 4]) and virus-infected (HeLa CCL2 [panel 5] and
MRC5.SV40 [panel 6]) cells after 6BG treatment (60 µM) for 15 h (26). The histograms and tables represent the gated cell
populations (events, y axis) and percentages, respectively,
with different DNA contents stained by PI (FL2-A on the x
axis defines the G1, S, or G2 cells). Ctr,
control. (B) Immunoblot of MGMT and R-MGMT by Pab.MGMT in total cell
extracts. Cell lines are numbered as in panel A. Control indicates
untreated samples, whereas 6BG indicates 6BG-treated (2 h) samples. The
6BG+V8 panel shows the 6BG-treated samples digested with protease V8
for R-MGMT analysis (3). Two hundred micrograms of cell
extract/lane was used. (C) Immunoblot of ER as for panel B by Pab.HC20.
(D) Immunoblot of SRC-1 as for panel B by the antibody Pab.N19.
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6BG and MeI (a DNA-damaging agent) block E2-stimulated growth of
ER-positive cells.
The above-described results raise the question
of whether the specific conversion of active MGMT to R-MGMT by 6BG
inhibits the growth of MGMT+ ER+ cells. To
address this, we compared 6BG treatment with the effect of withdrawal
of estrogen-like stimuli on these ER+ cells (using medium
without phenol red and steroid-depleted serum, Cdex medium
[37]), since some ER-responsive genes regulate cell proliferation (31). The FC analysis in Fig. 2A and
D shows, respectively, that the MCF7 and
T47D cultures grown in Cdex medium contain fewer S-phase cells than
those grown in full medium with 6BG. These results suggest that 6BG may
antagonize ER. Thus, we analyzed cells grown in Cdex medium treated
with 6BG or MeI (because MGMT is a DNA repair enzyme, we tested whether
generation of R-MGMT by an alternative means involving DNA damage by
MeI will behave similarly) followed by stimulation with E2, an
activating ligand for ER. The FC analysis shows that 6BG and MeI behave
similarly in blocking E2-stimulated growth on cells grown in Cdex
medium; see the S-phase cells of E2, E2 plus MeI, and E2 plus 6BG in
Fig. 2B and E. Again, most MGMT in the drug-treated cells was converted to R-MGMT (Fig. 2C and F). Thus, modification of MGMT may be causal in
blocking the activation of ER by E2, because 6BG and MeI convert MGMT
to R-MGMT via independent pathways (26).
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FIG. 2.
6BG and MeI block 17- estradiol (E2)-stimulated
growth of ER-positive cells. (A and D) Histograms from FC analysis of
the populations of MCF7 and T47D cells, respectively, at
G1, S, and G2 phases after culture in full
medium alone (Ctr), Cdex medium, and full medium with 6BG for 15 h. (B and E) Summary of the percentages of cells at G1, S,
and G2 phases for cells grown in Cdex medium alone (Cdex),
treated with E2 for 15 h (E2), treated with MeI (1 mM) followed by
E2 (E2+MeI), and treated with 6BG (50 µM) followed by E2 (E2+6BG). (C
and F) R-MGMT analysis by protease V8 and Pab.MGMT in extracts from the
cells analyzed in panels B and E after 2 h of E2 treatment.
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The inhibition of ER activity by 6BG and MeI is independent of
p53.
To ensure that the failure of E2 in activating the ER
responses in the ER+ MGMT+ cells treated with
the DNA-damaging agent MeI is indeed related to the conversion of MGMT
to R-MGMT but not p53, we compare the levels of the p53 protein in
these treated cells with those in the 
-irradiated cells (11,
15). The Western blots in Fig. 3A
show that p53 levels in the MCF7 cells exposed to the dosage of irradiation that is sufficient to induce growth arrest in these cells
(Fig. 3D) are significantly higher than in those cells undergoing
growth arrest induced by 6BG or MeI treatment. This is not due to a low
dosage of MeI being used, since the majority of MGMT in the MeI-treated
cells is converted to the protease V8-sensitive R-MGMT (compare Fig. 3B
and C) through the repair of the 6RG lesions in the DNA induced by MeI
or the direct alkylation of MGMT by MeI (26). Furthermore,
the T47D cells, which undergo growth arrest induced by 6BG or MeI
treatment (Fig. 1A and 2E), express high levels of the mutated p53
protein (4).
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FIG. 3.
Inhibition of ER response by 6BG and MeI is independent
of p53. MCF7 cells grown in normal medium were treated with 2 Gy of irradiation (from a cobalt 65 source), 60 µM 6BG, or 1 mM MeI. Total
cell extracts were prepared at 1, 3, and 6 h after treatment for
Western blot analysis using Mab.DO1 for p53 and Mab.3B8 for MGMT as
shown in panels A and B, respectively. The cell extracts were also
treated with protease V8 to confirm the presence of R-MGMT as shown in
panel C. Panel D shows the FC analysis of the cell population profiles
24 h after treatment with 6BG, Mel, and irradiation. Ctr,
untreated control cells. The inserted table gives the summary of the
average percentage of cells at G1, S, and G2
from three independent experiments.
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R-MGMT disrupts the ER-SRC-1 interaction and fails to associate
with the CBP/p300 complex.
The above-described results indicate
that the growth arrest induced by 6BG and MeI in ER+
MGMT+ cells is independent of p53, since the protein is
poorly induced under these drug treatments. What molecular mechanism
might lie behind the above observations? Since R-MGMT adopts an altered conformation to expose the VLWKLLKVV domain
(26) containing the LXXLL motif found in steroid hormone
coactivators for their binding to nuclear hormone receptors
(13), we investigated whether R-MGMT can regulate ER.
First, we quantified the levels of the two proteins in the cell context
using purified recombinant proteins. Figure
4A shows that MCF7 or T47D cell extracts
contain ~6-fold more MGMT than the ER proteins (~80 ng of MGMT [21
kDa] and ~40 ng of ER [67 kDa] are present in 200 µg of cell
extract). Thus, there is potentially sufficient R-MGMT generated by
drug treatment to mediate the function of ER, since >90% of cellular
MGMT can be converted to R-MGMT (Fig. 2C and F). We then studied the
ER-SRC-1 complex (27) by analyzing the amount of
ER coimmunoprecipitated with SRC-1 from various nuclear extracts. The
immunoblot in Fig. 4B shows that ER coprecipitates with SRC-1 from
normal cell extracts but coprecipitates poorly with SRC-1 from
those treated with 6BG and MeI. This explains the overriding effect of
the drugs on E2-driven cell proliferation (Fig. 2B and E), since SRC-1
coactivates transcription by ER (27). However, does R-MGMT
promote the dissociation of ER from SRC-1? We therefore tested whether
R-MGMT interacts with ER. Interestingly, MGMT was present at high
levels in the ER immunoprecipitates from the drug-treated cells
containing R-MGMT but not in those from the untreated cells containing
active MGMT (Fig. 4C), suggesting that ER preferentially binds the
R-MGMT. This is not the case for the ER+ MGMT
SV-ER cells (see Fig. 6E, lane 2), which are ER
MGMT MRC5.SV40 cells stably expressing exogenous ER
(interestingly, we were unable to obtain "native" ER+
MGMT cells) (Fig. 4D). Unlike the case with
ER+ MGMT+ MCF7 cells, as shown in Fig. 4B, the
immunoprecipitable ER-SRC-1 complex remained intact in the
ER+ MGMT SV-ER cells treated with 6BG or MeI
(Fig. 4E). These results establish a unique role for R-MGMT in these
events.
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FIG. 4.
R-MGMT disrupts the ER-SRC-1 interaction and fails to
associate with the CBP/p300 complex. (A) Quantification of MGMT and ER
proteins. Lanes labeled MCF7 and T47D contain 200 µg of total cell
extracts, whereas lanes with numbers contain the purified recombinant
MGMT and ER proteins, with numbers indicating amounts in nanograms
(ng). Western blotting was performed with Mab.3B8 for MGMT and with
Pab.HC20 for ER. (B) Immunoblot analysis of SRC-1 and ER in SRC-1
immunoprecipitates from MCF7 nuclear extracts. The lanes labeled Ctr,
Mel, and 6BG are untreated (control), Mel (1 mM)-treated, and 6BG (50 µM)-treated cells grown in full medium for 2 h, respectively.
The top panel is the immunoblot of the SRC-1 protein visualized by
Pab.N19 in the SRC-1 Mab.677-F11 immunoprecipitate, and the bottom
panel is the coimmunoprecipitated ER shown by Pab.HC20. (C) Immunoblot
analysis of ER (Mab.F10) and MGMT or R-MGMT (Mab.3B8) in ER
immunoprecipitates (Pab.H184), similar to panel B. (D) Survey of breast
cells. Immunoblots of ER and MGMT in reported breast cell lines are
shown: note the absence of the dual ER-positive and MGMT-deficient
phenotypes. (E) Immunoblot analysis of SRC-1 and ER in SRC-1
immunoprecipitates from SV-ER (ER+ MGMT)
nuclear extracts, similar to panel B: note that the levels of ER
protein were not affected by MeI and 6BG treatments compared to the
MCF7 (ER+ MGMT+) cells in panel B. (F)
Immunoblot analysis of CBP/p300 (Pab.451) and MGMT (Pab.MGMT) and in
CBP/p300 immunoprecipitates (Mab.CBP/p300), similar to panel B.
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To assess its proximity to transcriptionally active ER-SRC-1 complexes
in the cell, we analyzed MGMT in the immunoprecipitates
of CBP/p300,
which are transcription integrators for various nuclear
receptor-coactivator complexes (
40,
43). Figure
4F
shows that
MGMT was recovered at high levels from normal cell extracts
but
not from drug-treated extracts, suggesting that after MGMT was
converted to R-MGMT in cells exposed to alkylating agents, R-MGMT
might
migrate from the CPB/p300-containing complex to bind proteins
such as
ER.
The LXXLL motif of R-MGMT interacts with ER in vitro and in
vivo.
Since results of the above-described immunoprecipitation
experiments strongly suggest that there is a close relationship between ER and R-MGMT, we tested whether the exposed LXXLL motif of R-MGMT can
bind to ER directly by using synthetic peptides containing the LXXLL
motifs of MGMT and CBP (as a control) in competition experiments
(13). These peptides were added to the recombinant ER-
before binding to the immobilized glutathione S-transferase fusion protein of the unique K107L-MGMT mutant (see the scheme in Fig.
5A, which adopts an altered conformation
[3] identical to that of R-MGMT with an exposed
VLWKLLKVV domain [26]). The immunoblot in
Fig. 5B confirms that the K107L mutant preferentially binds to ER-
compared to the wt MGMT. This binding is sensitive to both Wt-CBP and
Wt-MGMT peptides (peptides 1 and 3 in Fig. 5C) but not mutant peptides
(2 and 4) substituted in a conserved leucine residue, indicating that
the intact LXXLL motif is critical for binding of R-MGMT to ER-.
Similar results were obtained when R-MGMT was generated via the
TATAC6MGTATA oligonucleotide substrate (18) (data not shown).
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FIG. 5.
The LXXLL motif of R-MGMT binds to ER in vitro and in
vivo. (A) The scheme for binding of recombinant ER- to immobilized
GST-(K107L)MGMT. (B) Immunoblot of recombinant ER- (by Mab.F10)
bound to immobilized GST-(wt)MGMT and GST-(K107L)MGMT
(visualized by Mab.3B8). (C) Peptide competition. The top panel is the
sequence of the peptide used. Peptides (7 µg) were added to the
ER- before binding to the immobilized GST-(K107L)MGMT. The
associated ER- was analyzed by immunoblot using Mab.F10. (D)
Mammalian two-hybrid assay. The top panel shows the region of SRC-1
(NR) used, similar to MGMT in size and in positioning of the LXXLL
motif. Codons are numbered. The bottom panel shows the average
luciferase activity obtained from three independent experiments in the
ER MGMT+ HeLa CCL2 cells normalized to the
control -Gal activities obtained. V represents the VP-16-containing
vector, and M represents the GAL4 DNA-binding domain-containing vector.
The fusion constructs are V-K107L-MGMT, V-SRC-1 (NR), and M-ER. The
luciferase activities were normalized to -Gal activities from
triplicate experiments. (E) Effect of 6BG on mammalian two-hybrid
assay. The experiment is similar to that shown in panel D except that
the ER MGMT MRC5.SV40 cells were used and 6BG
(25 µM) was added together with E2.
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Furthermore, in vivo mammalian two-hybrid analysis comparing K107L-MGMT
to a similar-size SRC-1 fragment containing the nuclear
receptor-interating domain (NR) in binding to ER-
showed equivalent
binding in the ER
MGMT
+ HeLa CCL2 cells (Fig.
5D). Similar results were obtained when
the ER
MGMT
MRC5.SV40 cells were used (Fig.
5E). In addition,
when R-MGMT
was generated in situ by using 6BG (added together with E2)
to
convert the expressed Wt-MGMT to R-MGMT, a positive signal was
observed (see the increase in luciferase activity of the Wt-MGMT
sample
treated with 6BG over that of the untreated sample in Fig.
5E).
However, we are unclear as to why generation of R-MGMT via
this
procedure is less efficient than the K107L mutant MGMT in
initiating
the two-hybrid response. Nevertheless, together these
in vitro and in
vivo data suggest that R-MGMT mimics the NR box
of SRC-1 in binding to
ER through sequences containing the LXXLL
motif.
The R-MGMT-equivalent K107L-MGMT mutant induces the growth arrest
of ER-positive cells.
The above observation that R-MGMT can behave
similarly to the NR box of SRC-1 in binding to ER (Fig. 5D) provides a
reason for the disruption of the ER-SRC-1 interaction observed upon
treatment with 6BG or MeI (Fig. 4B). This raises the question of
whether sequestering ER from the SRC-1-associated transcriptional
machinery by R-MGMT is the molecular event behind the growth arrest of
ER+ MGMT+ cells induced by 6BG or MeI
treatments (which generate R-MGMT [26]) (Fig. 1A and 2B
and E). To establish such a link, we analyzed the MCF7 cells by FC
after transient transfection with the cDNAs of wt and mutant (K107L)
MGMT. Figure 6A shows that cells
expressing the K107L-MGMT (i.e., R-MGMT) proteins (26) are
predominantly at the G1 phase, but the Wt-MGMT-expressing
cells are not (see the cell distribution histograms of cells stained by
MGMT antibody in the gated region R in panels d, e, and f). Thus,
generation of R-MGMT by expression of a conformational equivalent
mutant (K107L) MGMT protein alone is sufficient to inhibit the growth of ER-driven cells, similar to the 6BG or MeI treatments, which generate R-MGMT (Fig. 2).
View larger version (49K):
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|
FIG. 6.
Effect of R-MGMT on the cell cycle and transcription.
(A) Growth arrest. MCF7 cells were transfected with expression vector
(Ctr) or vectors fused with wt or K107L mutant MGMT cDNAs for 24 h
(19) before analysis by FC using dual channels to quantify
the fluorescence in the cells from the stainings of MGMT by Mab.3B8 and
of DNA by PI. Panels a, b, and c show the distributions of transfected
cells stained by MGMT Mab.3B8 (FL1-A, y axis) versus their
DNA contents (FL2-A, x axis). Cells with greater MGMT
stainings than the control (Ctr), due to the expression of the MGMT
cDNAs, are gated (the region R) to generate the histograms (d, e, and
f) where the cell populations (events, y axis) were plotted
against their DNA contents (x axis) representing
G1, S, and G2 phases. The arrow in panel c
indicates that a large population of cells expressing the K107L-MGMT
proteins are at G1 phase. (B) Inhibition of RNA synthesis.
Cells were labeled for 6 h with [3H]uridine after
being cultured under full medium (FM) (lane 2), FM with 6BG (lane 1, pretreatment with 60 µM 6BG for 2 h before labeling), Cdex medium
(lane 3), Cdex with E2 (lane 4) (pretreatment with 100 nM E2 for 2 h before labeling), or Cdex with E2 and 6BG together (lane 5)
(pretreatment with 6BG and E2 together for 2 h before labeling).
The labeled total RNAs isolated (2 µg/lane) were resolved on a 1%
agarose gel. The top panel is the autoradiograph of the membrane with
the labeled RNAs resolved by the agarose gel. The histogram is a
summary of the 3H counts from 2 µg of labeled RNAs
(averaged from three independent experiments). The bottom panel is the
description of the samples. (C) RT-PCR analysis of the levels of PR,
pS2, PBGD, and -actin mRNAs obtained from cells cultured for 24 h,
similar to panel B without [3H]uridine labeling. (D)
Abbreviations of the wt and Mu (K107L mutant) MGMT full-length (FL)
cDNAs used for transfection into the SV-ER cells (19). M
is the first methionine. (E) Reporter assay. Top panel, immunoblot of
the expressed ER (Pab.HC20) and MGMT (Pab.MGMT) proteins in SV-ER cells
grown in Cdex medium 24 h after cotransfection with ERE-Luc and
MGMT (Wt, Mu, Wt-2A, and Mu-2A) constructs followed by 6 h of
treatment with 1 µM E2. SV indicates the parental ER- and
MGMT-negative MRC5.SV40 cells. Lower panel, the corresponding
luciferase activities in the cell extracts.
|
|
The exposed LXXLL motif in R-MGMT suppresses ER-mediated
transcription.
Together these results demonstrate a direct
relationship between growth inhibition (Fig. 6A) and disruption of the
ER-SRC-1 complex (Fig. 4B) by R-MGMT generated in the ER+
MGMT+ cells. To understand the mechanism behind these
observations, we investigated the effect of R-MGMT on ER function
(i.e., ER-mediated transcription activities) in vivo by first studying
the effect of 6BG treatment on the incorporation of
[3H]uridine. Figure 6B shows that addition of 6BG to MCF7
cells grown in full medium indeed inhibits the incorporation of
[3H]uridine into the RNA; compare the labeled RNA in
samples 2 (control/FM) and 1 (with 6BG) in the autoradiogram (top
panel) and histogram. Further pulse-labeling of MCF7 cells cultured in
estrogen-depleted Cdex medium and then stimulated with E2 showed that
E2 activates transcription of these cells, as shown by the increased
[3H]uridine incorporation into the RNA, but fails to do
so in the presence of 6BG (compare samples 3 [control/Cdex], 4 [with
E2], and 5 [with E2 and 6BG] in Fig. 6B). These results indicate
that R-MGMT inhibits E2-mediated ER transcription. Consistent with this
observation, RT-PCR analysis of the mRNAs of the known ER-regulated progesterone receptor (PR) and pS2 genes (Fig. 6C, compare lane 1 with
lane 2 and lane 5 with lane 4) shows that their mRNA levels are
significantly lower in the 6BG-treated cells, but the -actin and
PBGD mRNAs (21) are not.
To show that the sequences containing the LXXLL motif of R-MGMT (or
K107L-MGMT itself) is involved in blocking ER-mediated
transcription,
we used the ER
+ MGMT
stable SV-ER cell line
and transfected full-length wt and mutant
MGMT cDNAs (see Fig.
6D). The
results portrayed in Fig.
6E show
that the Mu (K107L) construct
produced significantly less luciferase
activity (i.e., transcription
inhibition) in the luciferase reporter
assay for ERE in SV-ER cells
(
23). The residual transcription
activity observed for the
Mu sample probably arises from the background
ER activity of the
untransfected SV-ER cells, since immunostaining
showed that 60% of the
transfected cells express the MGMT protein
(data not shown).
Significantly, both the Wt-2A and Mu-2A constructs,
which contain
mutations in the LXXLL domain, show luciferase activities
comparable to
the control's. These results show that R-MGMT, which
binds to ER (Fig.
4C and
5B to E), blocks ER from transcription
that is activated through
the binding of the LXXLL motif of coactivators,
presumably to the
activation function 2 domain of ER (
25,
34).
This explains
the effects of 6BG or MeI treatment on the inability
of SRC-1
antibodies to immunoprecipitate ER (Fig.
4B) and failure
of growth
stimulation by E2 (Fig.
2B and E). Together, these results
thus
link transcription suppression of ER-responsive genes and
growth
inhibition mediated by R-MGMT.
| |
DISCUSSION |
Unlike histone deacetylase-mediated transcription suppression (via
the mSIN3 [45] or MeCP proteins [24]),
which cannot operate immediately, R-MGMT functions as a DNA
damage-induced transcription suppressor (Fig. 6E), providing timely
suppression of ER-mediated cell proliferation when cells are exposed
spontaneously to alkylating agents (Fig. 2). This serves two immediate
functions. First, cells that proliferate under the control of ER will
not enter S phase upon exposure to alkylating agents (Fig. 2B and E), thus avoiding 6RG-directed mutations during DNA replication (1). Secondly, even though alkylating agents can inflict
damage on the transcribing DNA of ER-regulated genes, this DNA will be blocked from transcription (Fig. 6E) to prevent the instant formation of mutated RNA (12). Thus, the "suicide" of MGMT upon
repair of the 6RG lesions immediately converts the DNA repair enzyme to
a transcription suppressor (R-MGMT), allowing it to directly couple
detection and the subsequent response specifically to the insult of
alkylating carcinogens. This mechanism should ensure that ER would not
activate proliferation of cells with damaged DNA, so that genomic
integrity could be maintained. Furthermore, it would be important to
establish how the activities of ER could be regulated when cells were
exposed to DNA-damaging agents other than alkylating agents given the
observed potency of ER in activating cell growth (see the significant
increases in the S-phase cells upon E2 stimulation in Fig. 2B and E)
and transcription activities (compare the [3H]uridine
incorporated into the RNA in lanes 3 and 4 of Fig. 6B) in the
ER+ cells.
One might also predict from the prevalent MGMT and ER dual positive
phenotypes (Fig. 4D) that in patients treated with 6BG (used in
clinical trials for brain tumors) (28, 29),
breast-derived tumors would be arrested (Fig. 1). Perhaps R-MGMT, as an
endogenous ER modulator that blocks ER-driven cell proliferation even
in the presence of its ligand E2 (see Fig. 2B and E and Fig. 6B, lane
5), would be as effective as the exogenous agent tamoxifen, a selective
estrogen receptor modulator that functions by competing with the ligand
of ER (9), which has been shown to reduce the breast
cancer incidence in high-risk women by 45% (36). In
retrospect, monitoring the MGMT levels in the ER+ cells
within the respective tissues of those women who received the drug
estrogen, which activates ER, during hormone replacement therapy may be
necessary, since sufficient MGMT levels must be maintained to control
the rapid growth of ER+ cells, due to stimulation by
estrogen, when they are exposed to environmental alkylating agents.
Failure to control cell proliferation upon DNA damage, thus allowing
damaged DNA to be replicated, could be a putative factor responsible
for the elevated cancer incidence in this group (5, 32).
Nevertheless, exposure to environmental alkylating agents is of concern
because these agents may also affect ER-dependent homeostatsis of
neural, skeletal, cardiovascular, and reproductive tissues
(16), since they rapidly convert MGMT in the cell to
R-MGMT (26).
Although a DNA repair pathway is shown here to directly impinge on cell
regulation, it remains unclear how different DNA lesions in the
transcribing DNA are perceived by the cell. The RNA polymerase, which
encounters every transcribing base residue, serves as an important
checkpoint protein for the presence of bulky lesions in the
transcribing DNA, since it cannot transcribe across these lesions.
Although it does not possess DNA repair activity, this stalled RNA
polymerase orchestrates the effective removal of the bulky DNA lesion
in transcribing DNA by recruiting the required DNA repair factors
(22, 33). Thus, the high-fidelity RNA polymerase enables
the cell to regulate transcription as well as repair when bulky DNA
lesions are formed in the transcribing DNA. However, what could be the
mechanism behind the repair of those DNA lesions (i.e., 6RG) that
escape the editing mechanism of RNA polymerase? Such a mechanism would
demand a constant surveillance at the sites of active transcription by
DNA repair factors that are also capable of overseeing the
transcription activities on the DNA. MGMT fulfills some of these
requirements. First, MGMT as a DNA repair factor is constitutively
present at active transcription sites, whereas R-MGMT, as a
transcription suppressor (Fig. 6E), appears instantly upon exposure to
alkylating agents (2). Second, active MGMT is a component
of the CBP/p300-containing complex (Fig. 4F) that integrates external
signals to activate the transcription activities of nuclear receptors
(40, 43). Furthermore, CBP/p300 is a histone acetylase
(17), which can modify the histone octamer in the
nucleosome to poise the DNA for transcription (41) and also expose the DNA to undesirable damage by mutagens (2). Thus, it is strategic for MGMT to be a component of the
CBP/p300-containing complex (Fig. 4F) in linking DNA repair events and
transcription regulation to deal with the 6RG lesions in the damaged
transcription-active DNA prior to their transcription by RNA polymerases.
| |
ACKNOWLEDGMENTS |
Alvin K. C. Teo and Hue Kian Oh contributed equally to this work.
We thank E. Manser for critical reading of the manuscript, R. Moschel
(National Cancer Institute) and D. B. Yarosh (Applied Genetic
Inc.) for 6BG, B. W. O'Malley (Baylor College of
Medicine) for SRC-1 antibody, V. Yu for the ER and ERE constructs, R. Kaushik for SV-ER cells, W. Stuenkel for advice, L. S. H. Chuang and K. S. W. Li for discussions, and Y. H. Tan
and NSTB Singapore for support.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Chemical
Carcinogenesis Laboratory, Institute of Molecular and Cell Biology,
National University of Singapore, 30 Medical Dr., Singapore 117609, Republic of Singapore. Phone: (65) 874 3763 or (65) 874 3797. Fax: (65) 779 1117 or (65) 775 9582. E-mail:
mcblib{at}imcb.nus.edu.sg.
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Molecular and Cellular Biology, October 2001, p. 7105-7114, Vol. 21, No. 20
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.20.7105-7114.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
