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J Biol Chem, Vol. 274, Issue 40, 28584-28589, October 1, 1999
From the Department of Medical Biochemistry, College of Medicine,
The Ohio State University, Columbus, Ohio 43210
We have shown previously that the heavy
metal-induced metallothionein-I (MT-I) gene expression is specifically
repressed in a rat fibroblast cell line (Ku-80) overexpressing the
80-kDa subunit of Ku autoantigen but not in cell lines overexpressing
the 70-kDa subunit or Ku heterodimer. Here, we explored the molecular
mechanism of silencing of MT-I gene in Ku-80 cells. Genomic
footprinting analysis revealed both basal and heavy metal-inducible
binding at specific cis elements in the parental cell line (Rat-1). By contrast, MT-I promoter in Ku-80 cells was refractory to any
transactivating factors, implying alteration of chromatin structure.
Treatment of two clonal lines of Ku-80 cells with 5-azacytidine, a
potent DNA demethylating agent, rendered MT-I gene inducible by heavy metals, suggesting that the gene is methylated in these cells. Bisulfite genomic sequencing revealed that all 21 CpG dinucleotides in
MT-I immediate promoter were methylated in Ku-80 cells, whereas only
four CpG dinucleotides were methylated in Rat-1 cells. Almost all
methylated CpG dinucleotides were demethylated in Ku-80 cells after
5-azacytidine treatment. To our knowledge, this is the first report
that describes hypermethylation of a specific gene promoter and its
resultant silencing in response to overexpression of a cellular protein.
Ku is an abundant nuclear protein that consists of two
polypeptides of molecular masses 80-86 and 70-72 kDa. It was first identified in the serum of a patient with scleroderma polymyositis overlap syndrome (1), and antibodies against this protein have been
detected in the sera of patients with various autoimmune diseases (2).
It can bind to the DNA ends (2, 3) as well as the internal DNA
sequences (4-7). Ku has been implicated in multiple cellular processes
that include DNA replication, recombination, repair, ATPase and
helicase activities, transcription, and alteration in chromatin
structure (2, 8). It is also involved in cell signaling (9), cell cycle
regulation (10), and maintenance of telomere length and telomere
silencing (8).
Ku can act both as a transcriptional activator and repressor depending
upon the promoter and growth conditions (2, 6, 7, 11-14). Previous
study in our laboratory demonstrated that specific antibodies against
Ku or peptide fragments of Ku could inhibit RNA polymerase I
transcription in vitro, which was overcome by the addition
of purified Ku protein to the reaction (6). Further study showed that
Ku could physically and functionally interact with another RNA
polymerase I transcription activator, CPBF (14), a protein that is
structurally and functionally related to USF, a helix-loop-helix-zipper
DNA binding factor (15, 16). On the contrary, Ku purified from the
growth-arrested cells inhibited polymerase I transcription, which could
be restored following addition of purified Ku from the control cells
(11).
In the course of our study on the regulation of metallothionein
(MT)1 gene expression (for
review, see Refs. 17 and 18) by heavy metals and oxidative stress, we
observed abolishment of the induction of MT-I and MT-II (19) (the two
predominant isoforms of MT) as a result of overexpression of the large
subunit (p80) of Ku in rat fibroblast cells, Rat-1. Interestingly,
overexpression of the small subunit (p70) of Ku or of the heterodimer
(p70 and p80) did not inhibit MT induction by the heavy metals. Nuclear extracts from the p80-overexpressing cells contained a repressor activity that could block transcription from the MT-I promoter (19).
The activities of two of the key transcription factors, Sp1 and MTF-1,
that modulate MT-I transcription were not modified in the extracts from
these cells. The present study was undertaken to determine the
molecular mechanism by which MT-I expression is repressed in the p80
overexpressing cells. This study showed that the promoter
hypermethylation is primarily responsible for the suppression of MT induction.
Cell Cultures, Treatment with 5-Azacytidine, Heavy Metals, and
Northern Blot Analysis--
Rat-1 (parental cell line) as well as cell
lines that overexpress p70 subunit (R70-15), p80 subunit (R80-1 and
R80-6), and both subunits (R7080-6) were generously provided by Gloria
Li, Memorial Sloan Kettering Institute. For convenience, overexpressing cell lines were also designated Ku-70, Ku-80, and Ku-7080,
respectively. All experiments except that described in Fig.
2B were performed using the clonal isolate R80-1 (designated
Ku-80 throughout the text). In the experiment described in Fig.
2B, R80-1 (Ku-80) and another clonal isolate, designated
R80-6, were used. The culture conditions and treatment with the heavy
metals were described earlier (19). For 5-AzaC treatment, Ku-80 cells
at 25-30% confluency were grown in presence of increasing
concentration of the analog for 72 h. RNA isolation and Northern
blot analysis were performed as described (19).
In Vivo Genomic Footprinting--
In vivo methylation
of cellular DNA by dimethyl sulfate (DMS) and the subsequent DNA
extraction were done following the protocol of Mueller and Wold (20).
The procedure of Ping et. al (21) was followed for
ligation-mediated (LM)-PCR. MRE and MLTF/ARE sites (adeno major late
transcription factor/antioxidant response element) were analyzed using
one set of upper strand- and one set of lower strand-specific primers.
The primers used to read the lower strand were: RMTI-5'-1,
5'-ACATGATGTTCCACACGTCAC; RMTI-5'-2, 5'-TGTTCCACACGTCACACGG; and
RMTI-5'-3, 5'-CACACGTCACACGGGTCCTC. The annealing temperatures
for this set of primers were 58, 61, and 64 °C, respectively.
The sequences of primers to read the upper strand were:
RMTI-3'-1, 5'-TTAGCGGACAGTCTGCTCTC; RMTI-3'-2,
5'-GCGGACAGTCTGCTCTCTTTATAG; and RMTI-3'-3,
5'-CTGCTCTCTTTATAGTCGTTGGACGG. The annealing temperatures were
57, 60, and 64 °C, respectively.
Bisulfite Genomic Sequencing--
Genomic DNA isolated from
different cell lines were treated with sodium bisulfite according to
Clark et. al (22) with some modifications. MT-I promoter
from
The PCR product was directly sequenced using fmolTM
sequencing kit (Promega) with the S2 and A2 primers.
The MT-I Promoter in Ku-80 Cells Is Refractory to the Transacting
Factors, as Revealed by In Vivo Genomic Footprinting--
Previous
study (19) in our laboratory demonstrated that Ku-80 cells (cells
overexpressing the large subunit of the protein Ku) were unable to
induce MT-I or MT-II in response to heavy metals such as
CdSO4 or ZnSO4. Under this condition, the
parental Rat-1 cells, a fibroblast cell line, and Ku-70 cells (cells
overexpressing the small subunit of Ku) or Ku-7080 cells (cells
overproducing both subunits of Ku) could induce the gene by the toxic
metals. This study suggested that the noninducibility of MT-I gene in Ku-80 cells was because of the existence of a repressor in the nuclear
extract prepared from Ku-80 cells (19). Alternatively, overexpression
of p80 could result in altered chromatin structure that inhibits access
of positive factors to the corresponding regulatory elements in the
promoter. To address the latter issue, we took advantage of in
vivo genomic footprinting (IVGF) to analyze and compare the state
of MT-I promoter occupancy in Rat-1 and Ku-80 cells before and after
exposure to heavy metals. This would allow us to identify the
sequence-specific DNA-protein interactions that are unique to both cell
lines, and potential alterations of these interactions specifically in
the parental cells after exposure to heavy metals.
IVGF analysis of the MT-I promoter was performed by LM-PCR with primers
designed to amplify the sequence from
Heavy metal-induced footprinting was observed in the lower strand at
MRE-d element where varying levels of protection of the G-residues
spanning this element were detectable upon Zn2+ or
Cd2+ treatment of the Rat-1 cells (Fig. 1B,
lanes 3 and 4). Distinct footprinting of MRE-c
element and the overlapping MRE-c' element were clearly detectable in
the lower strand of MT-I promoter of Rat-1 cells, which were
indistinguishable for Zn2+- and Cd2+-treated
samples (Fig. 1B, lanes 3 and 4). The
G-residues encompassing MRE-e, MRE-b, and MRE-a element of the lower
strand of MT-I promoter from the heavy metal-treated Rat-1 cells were
also protected (Fig. 1B). In addition, Zn2+- and
Cd2+-induced footprinting was observed at the composite
element MLTF/ARE in the lower strand of control Rat-1 cells when
compared with the naked G-ladder (Fig. 1B). The G-residues
in Sp1 binding element were constitutively protected (Fig.
1C, lane 2, double arrow), and some
were hypersensitive in the upper strand of control Rat-1 cells (Fig.
1C, asterisk) before and after ZnSO4
or CdSO4 treatment. A very prominent DMS reactivity
(hypersensitive residue) was observed at another Sp1 binding site
overlapping with the MLTF/ARE element in the upper strand of MT-I
promoter from both Zn2+- and Cd2+-treated Rat-1
cells (Fig. 1C). On the contrary, none of the conspicuous constitutive and/or metal-induced footprinting observed in Rat-1 cells
were visible in Ku-80 cells irrespective of metal ion treatment (Fig.
1, B and C). This observation indicates that
overexpression of p80 protein results in altered chromatin structure.
Such chromatin modification is likely to lead to a conformation of the
MT-I promoter refractory to any positive factor binding, which could
explain the lack of heavy metal-induced MT-I induction in Ku-80 cells.
MT-I Gene Is Activated by Various Inducers in Ku-80 Cells after
5-AzaC Treatment--
The failure of the positive factors to footprint
on the promoter of other genes silenced because of methylation of CpG
dinucleotides has been reported by many laboratories (23). Based on
these published reports and our own IVGF data with MT-I gene (Fig. 1), we reasoned that MT-I promoter may be silenced in Ku-80 cells because
of promoter methylation. To test this possibility, we determined the
effect of 5-AzaC, a potent DNA demethylating agent (24) on MT-I
expression. As treatment with 10 µM 5-AzaC for 24 h
did not result in induction of the gene in response to heavy metals
(19), we first determined the concentration of the cytosine analog and
duration of treatment that can activate MT-I gene in Ku-80 cells.
Increase in 5-AzaC concentration from 10 to 20 µM and
time of incubation with the drug from 24 to 72 h resulted in
significant expression of MT-I mRNA after CdSO4
treatment (Fig. 2A). These
data showed that MT-I gene can indeed be induced in Ku-80 cells (R80-1
clonal line) by heavy metals after prolonged treatment with relatively
high concentration of 5-AzaC. The MT-I promoter methylation in the
clonal cell line used in the present study may be because of a critical
chance event of methylation that contributed to further methylation. To
rule out this possibility, we used another randomly selected clonal
isolate (R80-6) of p80 overexpressing cells. This study showed that
MT-I gene is repressed in these cells as well and that demethylation
with 5-AzaC reactivated the promoter (Fig. 2B). The
silencing of MT-I gene in the cells overexpressing the 80-kDa subunit
is, therefore a specific event. After demethylation with 5-AzaC, MT-I
gene could be activated by other inducers as well, e.g.
zinc, dexamethasone, cycloheximide (data not shown). We then compared
the level of induction of MT-I mRNA in Rat-1 cells following
exposure to CdSO4 to that of Ku-80 cells treated with
5-AzaC plus CdSO4 (Fig. 2C). Under this
condition, MT-I mRNA level in the 5-AzaC-treated Ku-80 cells
reached almost the same level as that in Rat-1 cells. We could not
detect any basal expression of MT-I in Ku-80 cells after 5-AzaC
treatment. This data suggests that hypermethylation of MT-I gene plays
a key role in its silencing in Ku-80 cells.
All CpG Elements within MT-I Promoter Are Methylated in Ku-80
Cells--
To ensure that the activation of MT-I gene by various
inducers after 5-AzaC treatment was indeed because of demethylation of
the promoter, we performed bisulfite genomic sequencing before and
after the drug treatment. Sequence analysis of MT-I promoter (
Completion of bisulfite conversion of the genomic DNA isolated from the
five different cell samples were confirmed by Tsp509I digestion. The restriction site for Tsp509I (
To study the status of all 21 CpG base pairs, we sequenced the
amplified DNA from all five cell cultures (see Fig.
4 for schematic representation of the
sequencing data). Interestingly, all 21 CpG base pairs (between
Sequencing of bisulfite-converted DNA from Ku-80 cells treated with
5-AzaC showed extensive demethylation of the MT-I promoter. This
explains the ability of 5-AzaC-treated Ku-80 cells to express MT-I upon
heavy metal treatment as observed in Northern blot analysis (Fig. 2).
This particular batch of 5-AzaC-treated Ku-80 cells retained one
methylated CpG at Although the role of Ku and associated DNA-PK has been well
established in V-D-J recombination and double strand DNA
break repair, the mechanism by which Ku regulates expression of various genes at the transcriptional level is still an enigma. Earlier studies
showed that overexpression of the p70 subunit of Ku or the heterodimer
represses induction of Hsp-70 protein (13, 25). The p80 subunit of Ku
can function as a receptor for somatostatin (9), whereas the small
polypeptide (p70) can directly interact with the proto-oncogene
p95vav (26) and GCN5, a transcriptional adapter
that has chromatin-modifying activity (27). The present study using
different clonal isolates of Rat-1 cells overexpressing the large Ku
subunit, has clearly demonstrated for the first time that
overproduction of a single subunit of a cellular protein can
hypermethylate and consequently silence the promoter of a specific
gene. These results implicate that the individual subunits of Ku can
play important regulatory roles in cellular functions. Although Ku
exists predominantly as heterodimer, a certain population of this
protein may also exist as homodimers which could exert their specific
functions. The ratio of homodimer to heterodimer may vary with the cell
type and under certain physiological conditions and disease states.
Because the Ku homodimers are generally unstable, they are degraded
rapidly (2). Consequently, the amount of p80 in Ku-80 cells is
considerably less than that in Ku-7080 cells where both p70 and p80 are
overexpressed (19, 25). The overproduction of any individual subunit
under certain physiological conditions or in pathological states may,
therefore, have gone undetected. We have recently demonstrated that
MT-I promoter is hypermethylated in a rat hepatoma and a mouse
lymphosarcoma cell line (relative to the parental cells) which resulted
in the repression of MT-I expression in these cancer
cells.2 Chromatographic
fractionation of the nuclear extracts from the hepatoma has frequently
yielded fractions that contain variable amounts of Ku
homodimers.3 This observation
is consistent with the potential role of Ku subunits in the methylation
of some promoters, which results in their inactivation.
Previous study in our laboratory showed that only the cells that
overproduce the large subunit of Ku fail to express metallothionein gene and that the suppression of MT-I transcription is at least, in
part, because of the production of a repressor in these cells (19).
This conclusion was reached by studying the in vitro
transcription of MT-I promoter in nuclear extracts derived from the
wild-type and mutant cells. This study did not suggest the role of
promoter methylation along with the production of an active repressor
in silencing the MT-I gene. The present data have clearly demonstrated that long term treatment of the cells with higher concentration of
5-AzaC was essential to remove the inhibitory methyl groups from
methylated CpG residues in MT-I promoter.
The methylation of four CpG elements of twenty one such dinucleotides
in the MT-I promoter of Rat-1 cells did not affect the ability to
express MT-I in response to heavy metals. The persistence of DNA
binding activity of MTF-1, the key transcription factor for MT-I
induction, in vitro (gel shift assay) or ability to
transactivate in vivo (transient transaction assay) (28)
following methylation of some MRE sites may probably explain the
capability of Rat-1 cells to express MT-I despite methylation of a few
key cis elements. Interestingly, the DNA binding and transactivation
property of the zinc finger protein Sp1 are also not inhibited upon
methylation of its binding site (28). The differential methylation
pattern of MT-I promoter in Rat-1 and Ku-80 cells leads us to postulate that the methylation of just a few key cis elements in Ku-80 cells alone may not cause MT-I gene silencing. Rather, extensive methylation of the promoter is likely to recruit the methyl CpG binding proteins along with repressors of transcription, like histone H1 or Sin3A (29)
that leads to alteration in the chromatin structure and consequently
gene silencing. The repressor detected in our earlier study in Ku-80
cell extract (19) is probably a methyl C binding protein (MeCP), as it
has been shown earlier that MeCP can inhibit transcription in
vitro from unmethylated as well as methylated promoters depending
upon the assay conditions (30). Further, overexpression of MeCP2 is
known to inhibit Sp1-activated transcription of human leukosialin gene,
although methylation of Sp1 binding site does not interfere with its
binding (31). Preliminary UV cross-linking studies have shown that the
activity of a MeCP is significantly higher in nuclear extract from the
Ku-80 cells compared with that from Rat-1 cells. Alternatively, it is
conceivable that a repressor different from MeCP may function in
concert with the methylated promoter to achieve repression of MT
induction in Ku-80 cells.
It is unlikely that a repressor protein binds directly to the promoter
(between Ku-80 homodimer by itself or via a signaling mechanism might have
initiated MT-I promoter methylation and subsequent silencing of the
gene. Direct addition of recombinant p80 (expressed from histidine-tagged p80 in reticulocyte lysate) to the in vitro
transcription system from Rat-1 cell extract did not inhibit MT-I
promoter activity in vitro (19). These data do not, however,
preclude the possibility of a direct role of p80 in the MT-I promoter
hypermethylation in vivo. To test the possible activation of
DNA methyl transferase in Ku-80 cells that could result in
hypermethylation of MT-I promoter, we measured the enzyme activity in
the whole cell extract prepared from the cell lines overexpressing
different subunits of Ku. The activity of this enzyme in these cells
was similar to that in the parental cell line
(Rat-1).4 These results
clearly show that MT-I promoter methylation in Ku-80 cells was mediated
by some mechanism(s) other than activation of DNA-methyl transferase.
Finally, the relative specificity of MT-I promoter methylation
following overexpression of the 80-kDa subunit of Ku deserves comment.
We have examined the expression of some growth suppressors (e.g. p16, p53) and housekeeping genes (e.g.
Hsp70, heme oxygenase I) in Ku-80 cells. It is known that p16 and p53
promoters are hypermethylated and consequently silenced in many
different types of cancers (32). None of these genes were silenced in
the Ku-80 cells (data not presented). Furthermore, the MT-I promoter
was inducible by heavy metals in the cells that overproduce the smaller subunit of Ku or both subunits together (19). Differential display of
genes or related techniques should be performed to identify other genes
that are suppressed in the Ku-80 cells. Clearly, overexpression of just
the large subunit appears to trigger a signal transduction pathway that
leads to hypermethylation of MT-I promoter and its silencing. The
challenge for future studies is to identify the step(s) that leads to
hypermethylation of a gene promoter as a result of p80 overexpression
and the mechanism by which MT-I promoter and probably a few other
promoters are susceptible to hypermethylation in Ku-80 cells.
We sincerely thank Dr. Gloria Li, Memorial
Sloan Kettering Institute, and Dr. Richard Palmiter, Washington
University, for providing Ku overexpressing cell lines and mouse MT-I
minigene, respectively.
*
This work was supported, in part, by a United States Public
Health Service grant (CA 61321) from the National Cancer Institute (to
S. T. J).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
To whom correspondence should be addressed: Dept. of Medical
Biochemistry, College of Medicine, The Ohio State University, 333 Hamilton Hall, 1645 Neil Ave., Columbus, OH 43210. Tel.: 614-688-5494; Fax: 614-688-5600; E-mail: jacob.42@osu.edu.
2
K. Ghoshal, unpublished data.
3
A. Ghosh and S. Jacob, unpublished data.
4
X. Dong, unpublished data.
The abbreviations used are:
MT, metallothionein;
5-AzaC, 5-azacytidine;
DMS, dimethyl sulfate;
IVGF, in vivo
genomic footprinting;
MRE, metal response element, MLTF/ARE, adeno
major late transcription factor/antioxidant response element;
LM-PCR, ligation-mediated polymerase chain reaction;
bp, base pair(s).
Hypermethylation of Metallothionein-I Promoter and Suppression of
Its Induction in Cell Lines Overexpressing the Large Subunit of Ku
Protein*
,,
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
304 to +148 bp was then amplified using two sets of primers from
the bisulfite-treated DNA. The primers used were: rMTI-T1,
5'-GAAAGGAGAAGTTGAGGATAGTGTGTTATG; rMTI-T2,
5'-TACCCCAAACCCCAACAAAAAACCATTC, annealing temperature was 60 °C.
The nested primers were: A2, 5'-CCAAACCCCTACAACTAAATATTC; and S2,
5'-GTATTGGATTAGTGATGGTTTGTAATAT, annealing temperature was
59 °C.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
226 to 16 bp, which
encompasses all cis-acting elements involved in the basal and
metal-induced expression of MT-I. Fig.
1A depicts the metal
regulatory elements and other key elements of the rat MT-I promoter.
Both Rat-1 and Ku-80 cells were treated with DMS before and after
exposure to ZnSO4 or CdSO4, and genomic DNA was
extracted, cleaved with piperidine, followed by amplification of the
promoter fragment by LM-PCR. Naked genomic DNA isolated from both Rat-1 and Ku-80 cells were treated in the same manner as intact cells and
amplified to provide the genomic G-ladder. DNA-protein interactions can
result in protection of G-residues from DMS reactivity that produce
less intense bands (indicated by arrows in Fig. 1,
B and C). Alternatively, such interactions can
result in more intense bands of G-residues exhibiting enhanced DMS
reactivity (indicated by asterisks in Fig. 1, B
and C) when compared with the naked DNA ladder or untreated
control. The DMS reactivity and cleavage pattern of both strands of
naked genomic DNA from Rat-1 and Ku-80 cells were identical (Fig. 1,
B and C).
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Fig. 1.
Genomic footprinting analysis of MT-I
promoter in Rat-1 and Ku-80 cells after induction with
ZnSO4 and CdSO4.
Cells untreated or treated with ZnSO4 (100 µM) or CdSO4 (30 µM) were
subjected to DMS treatment, followed by DNA extraction and piperidine
cleavage (see "Materials and Methods"). The naked DNA from both
wild-type and mutant cells were also treated with DMS and piperidine.
An identical amount of DNA (2 µg) from each sample was then subjected
to LM-PCR with primers specific for the upper and the lower strands.
A, schematic diagram of the MT-I promoter depicting cis
elements that are relevant to heavy metal-induced expression. LM-PCR of
the lower strand (B) and LM-PCR of the upper strand
(C) of MT-I promoter in Rat-1 and Ku-80 cells. Lanes
2, 3, and 4 represent Rat-1 cells that are
untreated or treated with ZnSO4 (100 µM) and
CdSO4 (30 µM), respectively; lanes
6, 7, and 8 correspond to similar samples
from Ku-80 cells, respectively; lanes 1 and 4 denote naked DNA from Rat-1 and Ku-80 cells, respectively.
Arrows ( 
) indicate G-residues that are protected, whereas
asterisks (*) represent hypersensitive G-residues.
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Fig. 2.
Northern blot analysis of MT-I expression in
response to heavy metals in Ku-80 cells after treatment with
5-AzaC. A, Ku-80 (R80-1) cells were exposed to
increasing concentrations of 5-AzaC for 72 h followed by
CdSO4 (30 µM) treatment, total RNA was
isolated and subjected to Northern blot analysis with
-32P-labeled, random-primed, mouse MT-I cDNA as
probe. B, Ku-80/R80-1 and R80-6 cells were exposed to 20 µM 5-AzaC for 72 h, followed by treatment with 30 µM CdSO4. Total RNA was isolated and
subjected to Northern blot analysis as above. C, Rat-1 and
Ku-80 cells were treated with 30 µM CdSO4
following treatment with 20 µM 5-AzaC. RNA was isolated
and subjected to Northern blot analysis as above. 18 S ribosomal RNA
was used in all samples to confirm equal loading of RNA.
225 to
+1 bp with respect to transcription initiation site) that harbors the
cis elements for most of the transacting factors revealed high density
of potential methylatable CpG dinucleotides (twenty-one) spanning this
region (Fig. 3A). Therefore,
it was essential to compare the methylation status of MT-I promoter in Ku-80 cells with that in Ku-70 and Ku-7080 cell lines, which express the smaller subunit of Ku and both subunits together, respectively. The
latter two cell lines can express MT-I mRNA at the same level as
the parental cell line (Rat-1) in response to heavy metals (19). For
this purpose, we performed bisulfite genomic sequencing of DNA isolated
from (a) Rat-1, (b) Ku-80, (c) Ku-80
treated with 5-AzaC, (d) Ku-70, and (e) Ku-7080
cells. The bisulfite treatment of the genomic DNA resulted in complete
conversion of unmethylated cytosines to uracils without affecting
methylated cytosines. Subsequent PCR amplification and sequencing
provided an accurate and consistent representation of mCpG
sequences.
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Fig. 3.
A, sequence of Rat MT-I promoter
proximal to the transcription start site. The methylatable CpG
dinucleotides are highlighted in the promoter sequence, along with
relative positions of the cis elements that are involved in heavy
metal-induced MT-1 expression. B, restriction enzyme
digestion profile of the bisulfite-converted MT-I promoter in Rat-1,
Ku-70, Ku-7080, Ku-80, and 5-AzaC-treated Ku-80 cells. Genomic DNA from
all five cell cultures were subjected to bisulfite treatment, followed
by PCR amplification of the upper strand of the MT-I promoter. One
microgram of the amplified fragment (452 bp) from each sample was then
digested with Tsp509I and BstUI.
AATT
)
does not exist in MT-I promoter and is generated only after bisulfite
conversion of unmethylated cytosine residues to uracils, which are
amplified as thymine during PCR. The Tsp509I digestion
analysis of PCR-amplified bisulfite-treated DNA from Ku-7080, Ku-70,
Rat-1, and Ku-80 cells treated with 5-AzaC and Ku-80 cells showed total
cleavage of amplified DNA from all five samples (Fig. 3B),
indicating completion of bisulfite reaction. To assess the existence of
CpG methylation, we digested all the DNA samples with BstUI
(CGCG). The MT-I promoter contains the restriction site for this
enzyme, which should be retained after bisulfite conversion if the
cytosine residues were methylated. Only the amplified DNA from Ku-80
cells showed cleavage with BstUI, indicating the presence of
methyl CpG dinucleotide in this cell line. The bisulfite conversion and
restriction enzyme digestion of the amplified DNA were performed at
least three times with different batches of chromosomal DNA.
225
to +1 site) in Ku-80 cells were methylated, whereas in Rat-1 cells only
four methylated CpG dinucleotides were present in the same promoter
stretch. It was logical to conceive that the additional CpG methylation
of MT-I promoter in Ku-80 cells was a direct or indirect outcome of p80
overexpression in these cells. Interestingly, none of the CpG elements
were methylated in Ku-70 or Ku-7080 cells, implying that methylation of
MT-I promoter occurred in the cell line that overexpressed specifically
p80 but not in cell lines overexpressing p70 homodimer or the p70/p80 heterodimer.
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Fig. 4.
Schematic representation of methylated and
unmethylated CpG base pairs spanning 225 bp to + 1 bp of MT-I
promoter. Genomic DNA was isolated from Rat-1, Ku-70, Ku-7080,
Ku-80, and 5-AzaC-treated Ku-80 cells and was treated with sodium
bisulfite as described (see "Materials and Methods"). MT-I promoter
was amplified using two sets of primers corresponding to the upper
strand of the bisulfite-converted DNA. The amplified DNA was sequenced,
and the data are represented schematically. The bold vertical
lines represent methylated CpGs, and plain vertical
lines denote CpGs as revealed by bisulfite genomic
sequencing.
112 site of the MT-I promoter, which did not
interfere with the expression of the gene.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
226 to +1 bp) and alters the chromatin conformation, as no
unique or new footprinting appeared in the MT-I promoter of Ku-80 cells
relative to that of Rat-1 cells. We extended our footprinting analysis
up to 350 bp of the promoter using another set of primers, which did
not indicate any DNA/repressor interaction in Ku-80 cells (data not
shown). The events occurring upstream of 350 bp cannot, however, be
discerned from the present data. Based on these data, it is reasonable
to conclude that overexpression of the 80-kDa subunit of Ku protein
silences MT-I gene in vivo by methylation of CpG island.
Methylated CpGs would then be bound by a specific MeCP(s), resulting in
altered conformation of chromatin structure that is inaccessible to the
transcription activators.
ACKNOWLEDGEMENTS
FOOTNOTES
These authors contributed equally to this work.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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