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J. Biol. Chem., Vol. 275, Issue 31, 23729-23735, August 4, 2000
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From Biochemistry and Biophysics, School of Molecular Biosciences,
Washington State University, Pullman, Washington 99164-4660
Received for publication, March 15, 2000, and in revised form, May 17, 2000
A-175-base pair fragment containing the
Xenopus borealis somatic 5 S ribosomal RNA gene was used as
a model system to determine the effect of nucleosome assembly on
nucleotide excision repair (NER) of the major UV photoproduct
(cyclobutane pyrimidine dimer (CPD)) in DNA. Xenopus oocyte
nuclear extracts were used to carry out repair in vitro on
reconstituted, positioned 5 S rDNA nucleosomes. Nucleosome structure
strongly inhibits NER at many CPD sites in the 5 S rDNA fragment while
having little effect at a few sites. The time course of CPD removal at
35 different sites indicates that >85% of the CPDs in the naked DNA
fragment have t1/2 values <2 h, whereas <26% of
the t1/2 values in nucleosomes are <2 h, and 15%
are >8 h. Moreover, removal of histone tails from these
mononucleosomes has little effect on the repair rates. Finally,
nucleosome inhibition of repair shows no correlation with the
rotational setting of a 14-nucleotide-long pyrimidine tract located 30 base pairs from the nucleosome dyad. These results suggest that
inhibition of NER by mononucleosomes is not significantly influenced by
the rotational orientation of CPDs on the histone surface, and histone
tails play little (or no) role in this inhibition.
In eukaryotic cells DNA is associated with histone proteins in the
structural hierarchy of chromatin, required to package the enormous
length of DNA into the small volume of a nucleus. The fundamental unit
of this hierarchy is the nucleosome core, which consists of 147 bp1 of DNA wrapped in 1.65 left-handed superhelical turns around an octamer of 2 each of the 4 core histones, H2A, H2B, H3, and H4 (1). This subunit is linked to
adjacent nucleosome cores by less tightly bound linker DNA, and the
entire unit repeats every 170-240 bp (2, 3).
It is believed that DNA damage and DNA processing events in eukaryotic
cells such as DNA repair and transcription are modulated by the
packaging of DNA into chromatin (4, 5). A clear example of chromatin
modulation of DNA damage is observed with formation of UV photoproducts
(6). The major UV photoproduct in DNA (cis-syn-cyclobutane pyrimidine dimer (CPD)) forms with a striking 10.3-base average periodicity in mixed sequence nucleosome cores (7). This periodic pattern of CPD formation reflects the bending of DNA molecules on the
histone surface (8-10), where the periodic compression of the minor
grove of DNA may modulate the [2 + 2]cyclo addition of adjacent 5-6
double bonds after UV photon absorption (11, 12). Indeed, CPDs cause an
overall bend of 7°-9° in the long axis of a double-strand DNA
molecule (13, 14), with possibly significant distortion of the
phosphodiester backbone on each side of the CPD site (15), and this may
be facilitated by compression of the minor groove of adjacent pyrimidines.
DNA repair in chromatin has been extensively examined in human diploid
fibroblasts, where two distinct phases exist in the time course of
repair in the genome overall (6, 16). There is an early rapid phase
(lasting 3-6 h after irradiation) and a late slow phase starting
between 5 and 16 h after irradiation, depending on the cell
strain. It was shown that repair synthesis is randomly distributed in
nucleosome core DNA during the late repair phase, whereas there is a
distinct bias toward the 5' ends of core DNA during the early repair
phase (17, 18). Surprisingly, during each of these phases, CPDs are
repaired at almost equal rates on the inner and outer faces of the DNA
helix, relative to the histone surface (18). This suggests that DNA
repair enzymes make little distinction between CPDs on different sides
of the DNA helix in most of the nucleosomes in human chromatin.
Nucleosome structure can modulate nucleotide excision repair (NER) in
the non-transcribed strand of an active gene in yeast (19).
Furthermore, nucleosome assembly of specific sequences significantly
inhibits the action of both UV photolyase and T4 endonuclease V (T4
endo V) at specific CPD sites in vitro (20, 21). Thus, even
though these enzymes have much different catalytic activities at CPD
sites (11), nucleosome assembly strongly inhibits the activities in
each case.
In this report, a 175-bp fragment containing the Xenopus
borealis somatic 5 S rRNA gene was used to examine the effects of nucleosome assembly on DNA repair by Xenopus oocyte nuclear
extracts. This combination of "substrate" and repair extract was
chosen because the 175-bp Xenopus somatic 5 S rRNA gene
fragment forms just a few well positioned nucleosomes in
vitro (10, 22), and Xenopus oocyte nuclear extracts
have a robust NER activity (23). These features allowed us to examine
the efficiency of removal of CPDs at specific sites within subdomains
of a rotationally positioned nucleosome.
Enzymes and Chemicals--
The [ 5 S rDNA Preparation--
After linearization of plasmid pKS-5S
(24) with either SexAI (for labeling the transcribed strand)
or SalI (for labeling the non-transcribed strand), DNA was
dephosphorylated with calf intestinal alkaline phosphatase (Roche
Molecular Biochemicals) and labeled with [ Irradiation with UV Light--
The DNA samples were diluted with
10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 0.2 mM phenylmethylsulfonyl fluoride (PMSF) to a final DNA
concentration of 50 ng/µl, irradiated under two low pressure Hg lamps
(Sylvania, model G30T8) providing predominantly 254-nm light at a flux
of 4.3 W/m2. UV flux was measured with a Spectroline
DM-254N UV meter (Spectronics Corp.).
Isolation of Nucleosome Core Particles--
Nucleosome core
particles depleted of linker histones (H1 and H5) were prepared from
chicken erythrocytes (Lampire Biological Laboratories) as described by
Libertini et al. (25). Core histones were characterized on
15% SDS-polyacrylamide gels (15 × 17 cm) run at 200 volts for
~3.5 h.
Trypsin Digestion of Core Particles--
Core histones were
depleted of their N-terminal tails by trypsin digestion as described by
others (20, 26). Briefly, core particles (7.7 mg/ml in 10 mM Tris-HCl, pH 7.2, 10 mM cacodylate, 0.2 mM EDTA) were adjusted to 50 mM NaCl, mixed
with 0.74 mg/ml trypsin (type XIII, tosylphenylalanyl chloromethyl
ketone (TPCK)-treated, Sigma) to make a final trypsin concentration of
6 µg/ml. After a 30-min incubation at room temperature, the reaction
was stopped with the addition of chicken egg white trypsin inhibitor
(Roche Molecular Biochemicals) to a final concentration of 60 µg/ml. The digestion time was determined by visualizing the tailless histones
on SDS gels as above.
Nucleosome Reconstitution--
Reconstitution was achieved by
histone octamer transfer as described previously (24). Briefly, 50 ng
of end-labeled 5 S rDNA was mixed with 42 µg of chicken erythrocyte
core particles (~20 µg of DNA) in 1 M NaCl, 10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 0.2 mM PMSF for 30 min at 4 °C. The final concentrations of
5 S rDNA and chicken erythrocyte core DNA in the reconstitution mixture was 0.63 ng/µl and 0.53 µg/µl, respectively. The samples were dialyzed against 0.6 M NaCl, 10 mM
Tris-HCl, pH 7.5, 1 mM EDTA, 0.2 mM PMSF for
12 h at 4 °C and then 50 mM NaCl, 10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 0.2 mM PMSF for
4 h at 4 °C to complete the reconstitution. As a mock control,
naked 5 S rDNA was also mixed with core particles in 10 mM
Tris-HCl, pH 7.5, 1 mM EDTA, 0.2 mM PMSF, and
50 mM NaCl without stepwise dialysis.
Characterization of Reconstituted 5 S rDNA Nucleosomes--
DNA
mobility shift was used to examine the fraction of 5 S rDNA nucleosomes
in the reconstituted population. DNA band shifts were observed on 6%
non-denaturing polyacrylamide gels (8.3 × 10.2 cm) in TBE buffer
(89 mM Tris, 89 mM borate, 2 mM
EDTA, pH 8.3) run for 1.2 h at 120 V. The fraction of 5 S rDNA
reconstituted was determined from integration of the two bands, as
described below.
Both enzymatic and chemical cleavage methods were carried out to
further characterize the 5 S rDNA nucleosomes. Exonuclease III
digestions were carried out with 9 µl (~6 ng of 5 S rDNA) of naked
5 S rDNA or reconstituted nucleosomes and incubated with 100 units of
exonuclease III (Roche Molecular Biochemicals) at 37 °C for
different times in a buffer containing 50 mM NaCl, 10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 3 mM MgCl2, and 1 mM
2-mercaptoethanol. The reaction was stopped with 0.1× volume of 200 mM Tris-HCl, pH 8.0, 5% SDS, and 50 mM EDTA,
as described (27). For DNase I digestions, 9 µl of reconstituted
nucleosomes (6 ng of 5 S rDNA) were treated with 7 units of DNase I
(Life Technologies, Inc.) for 1 or 2 min at room temperature, whereas
0.35 units of DNase I were used to digest the same amount of naked DNA
for 1.5 or 3 min at room temperature (28). The reaction was stopped by the addition of 0.1 × volume of 25 mM EDTA. Hydroxyl
radical footprinting was carried out on 9 µl of reconstituted
nucleosomes (~6 ng of 5 S rDNA) after dilution to 20 µl with TE (10 mM Tris-HCl, 1 mM EDTA, pH 8.0) (29). After
incubation with 2 µl of 20 mM sodium ascorbate, 2 µl of
0.4 mM Fe-EDTA, and 2 µl of 1.5% or 3%
H2O2 for 2 min at room temperature, the
reaction was stopped with 5 µl of 0.1 M thiourea and 2 µl of 0.2 M EDTA. After each of the reactions described
above, the DNA samples were purified by phenol extraction and ethanol
precipitation and run on an 8% polyacrylamide, 8 M urea
DNA sequencing gel (see below).
Repair Reactions--
Repair incubation with Xenopus
oocyte nuclear extracts was performed as described previously (23, 30).
Naked DNA or reconstituted nucleosomes containing ~6 ng of 5 S rDNA
were mixed with 2 µl of Xenopus oocyte nuclear extracts in
20 µl of J-buffer (10 mM HEPES, pH 7.4, 70 mM
KCl, 7 mM MgCl2, 0.1 mM EDTA, 2.5 mM dithiothreitol, 1% polyvinylpyrrolidone, and 10%
glycerol). The repair mixture also contained 0.25 mM each
of dATP, dGTP, dTTP, and CTP. All repair reactions were incubated at
25 °C for the time periods indicated in the text. Reactions were
stopped by freezing the samples at Mapping and Quantitation of CPDs--
Before T4 endo V
digestion, DNA was phenol extracted, ethanol-precipitated, and
resuspended in T4 endo V digestion buffer (20 mM Tris-HCl,
pH 7.4, 10 mM EDTA, pH 8.0, 100 mM NaCl, and 100 µg/ml bovine serum albumin). T4 endo V (1 µl of a 200-fold dilution of enzyme stock (400 ng/µl)) was then added, and the reaction was incubated at 37 °C for 30 min. After the addition of
sequencing gel loading buffer (0.05% bromphenol blue, 0.05% xylene
cylanol, 20 mM EDTA in deionized formamide) to stop the reaction, samples were heat-denatured and run on (29 × 96 cm) 8%
polyacrylamide, 8 M urea DNA sequencing gels for 2.5 h
at 1600 volts (31). The gels were then vacuum-dried, exposed to
(43 × 35 cm) PhosphorImager screens, and visualized on a
Molecular Dynamics (model 445-P90) PhosphorImager (Sunnyvale, CA). Band intensities were quantified using ImageQuaNT (Molecular Dynamics) and
PeakFit 4.0 (SPSS, Inc.) software. Broad scans of each gel lane
(~3/4 of the width) were obtained with ImageQuaNT software, and
nested peaks were deconvoluted before integration with PeakFit software
using basis spectrum line shapes of Gaussian plus Lorentzian curves
(32). In most cases, loading differences were corrected by normalizing
the intensity of each band to the sum of all bands in a lane. The
fraction of CPDs at each site was plotted for different incubation
times, and the t1/2 values (time for 50% of the
initial damage to be removed) was determined from fits to these data.
For Fig. 8, the absolute value rather than the relative percentage of
each band was used due to the fact that most of the bands run off the
gel. The relative percentage of a particular band (corresponding to a
specific CPD site) within each lane was used to calculate the percent
repair at different times. The average CPDs per strand was calculated
from the intensity of the intact fragment resistant to T4 endo V,
assuming a Poisson distribution of UV damaged fragments, as described
by Bohr et al. (33).
Characterization of Reconstituted 5 S rDNA Nucleosomes--
A
diagrammatic representation of the 175-bp 5 S rDNA fragment used in
this study is shown in Fig. 1. The
ovals show the two major positions of the 5 S nucleosome
relative to the various elements of the 5 S rRNA gene determined by
Panetta et al. (34) for a longer DNA fragment (249 bp) with
the Xenopus somatic 5 S rRNA gene. Nucleosomes were
reconstituted onto 5 S rDNA fragments by histone octamer exchange
from chicken erythrocyte (CE) core particles isolated from
H1/H5-stripped chromatin (25). Gel electrophoresis demonstrated that
these CE core particles contained stoichiometric amounts of intact core
histones and were depleted of histones H1 and H5 (data not shown). The
CE histone octamers were reconstituted onto 5 S rDNA by exchange
in high salt followed by stepwise dialysis (see "Material and
Methods"). DNA band shift analysis was used to monitor nucleosome
formation with both irradiated and non-irradiated 5 S rDNA fragments,
and under these conditions, at least 90% of the fragments were
reconstituted into nucleosomes (Fig.
2A). Moreover, band shift
experiments showed that nucleosomes are stable for at least 4 h
during repair incubation (data not shown).
To characterize these 5 S rDNA nucleosomes, three different types of
footprinting were performed (Fig. 2B). Exonuclease III is a
3'
Both DNase I and hydroxyl radical digestion provide information about
the rotational setting of DNA in nucleosomes. DNase I cuts the
phosphate backbone from the minor groove, which is restricted when
facing the histone surface, yielding an ~10-base repeat pattern on
denaturing gels (reviewed in Ref. 28). Naked DNA is cut more randomly
than nucleosome DNA, although the enzyme has a strong sequence bias
(Fig. 2B, lanes 5 and 6). With
hydroxyl radical cleavage, however, there is much less sequence
specificity (29), and these two methods complement each other when
evaluating the rotational setting of DNA in nucleosomes. The most
intense cleavage sites on the 5 S nucleosome by hydroxyl radical
occurred at Repair of 5 S rDNA Nucleosomes by Xenopus Oocyte Nuclear
Extracts--
Contrary to the low repair efficiency found in cultured
mammalian cell extracts (e.g. 35), Xenopus oocyte
nuclear extracts remove almost all CPDs from irradiated exogenous DNA
within a few hours (23). Therefore, these extracts were chosen for
examining repair of CPDs in the 5 S rDNA nucleosome, since CPD removal
at specific sites could be followed. For these experiments, the 175-bp 5 S rDNA fragment was UV irradiated, reconstituted into nucleosomes, and incubated with oocyte nuclear extracts as described in Conconi et al. (30). After different incubation times, 5 S rDNA was purified, cut with T4 endo V, and run on DNA sequencing gels as above.
As shown in Fig. 3, repair of most CPDs
in either strand of 5 S rDNA (or the disappearance of bands) was
strongly inhibited by nucleosome assembly (compare D and
N lanes). The decreased intensity of CPD bands should be
accompanied by an increased intensity of the whole length (or uncut)
fragment, which reflects the overall repair of the 5 S rDNA fragment.
As shown in Fig. 4, the overall repair
efficiency of each strand decreases upon nucleosome formation (compare
solid to dashed lines), in complete agreement
with the trend at individual CPD sites observed in Fig. 3.
These results can be compared by determining the percentage of CPDs
remaining at each site after different times of repair incubation.
Three examples are shown in Fig. 5 for
different short tracts of CPD sites (denoted by stars in
Fig. 3). Clearly, naked DNA has different repair rates than nucleosomal
DNA at two of these sites (+21CTTTC+25
and +54TTC+56). Furthermore, these slower
repaired CPDs in nucleosomal DNA were removed at different rates from
each other (compare top and middle panels in Fig.
5). Interestingly, a few CPD sites in nucleosomes were repaired almost
as rapidly as naked DNA (e.g. site
+58TCCC+61, Fig. 5, bottom panel).
The structural features of these sites are discussed below (see
"Discussion").
The t1/2 value of each CPD site was determined from
its repair curve, and these values are compared graphically over the
entire 5 S rDNA fragment in Fig. 6. Most CPD sites in naked DNA have t1/2 values of less than
2 h (Fig. 6, closed bars). However, careful inspection
of several different gels and subsequent quantitation of the results
indicates that the rate of repair at individual sites in naked 5 S rDNA
is quite variable. For example, extremely fast repair is observed at
sites CT+42, +54TTC+56,
+58TCCC+61, +64CCC+66,
CC+71, and TC+75 of the TS, whereas sites
Compared with naked DNA, repair of CPDs in 5 S rDNA nucleosomes is
slower at almost all sites, with most t1/2 values
being >2 h (Fig. 6, shaded bars).
Moreover, some CPD sites just outside of the predominant nucleosome
location (i.e. positions larger than +80 of the TS) are also
repaired slower. This may in part be due to the variation in nucleosome
translational settings and/or binding of the DNA ends by exposed basic
residues on the histone tails. However, some CPD sites continue to be
repaired efficiently in the nucleosome complex (e.g.
+58TCCC+61, Figs. 5 and 6). In addition, the
time course of repair at individual CPD sites relative to the other
sites observed for naked DNA are different from those observed for
nucleosomes. For example, one slow repair site of naked DNA,
+28CCC+30 of NTS, is repaired at an
intermediate rate in nucleosomes. Repair at sites
Repair of 5 S rDNA Nucleosomes Trimmed of Histone Tails--
The
N-terminal tails of the core histones containing a high proportion of
basic amino acids may play important roles in stabilizing nucleosome
structure, particularly in polynucleosome fragments (36). Therefore, to
examine their effect on NER of mononucleosomes, the histone tails were
removed from CE nucleosomes by trypsin digestion, as described by Ausio
et al. (26). Under these conditions, the tails are
efficiently removed from the four core histones as demonstrated by
their increased migration on SDS gels (Fig. 7A). As expected, when these
CE nucleosomes are used for reconstitution, the 5 S rDNA nucleosomes
migrate faster than the intact 5 S rDNA nucleosomes on native gels
(Fig. 7B). Importantly, the fraction of nucleosomes
reconstituted with the trypsin-digested CE core particles does not
change appreciably (Fig. 7B). However, removal of the
histone tails does not significantly enhance NER in 5 S rDNA
mononucleosomes. As shown in Fig. 7C for CPDs in the 3' half of the fragment (
Finally, we examined the correlation between site-specific NER and the
rotational setting of 5 S rDNA on the histone surface. For these
experiments, a 14-nt long pyrimidine tract in the transcribed strand
was analyzed in detail, since it spans more than one complete turn of
the 5 S rDNA helix (Fig. 8A).
Resolution of the 13 potential CPD-associated bands required a longer
gel running time (Fig. 8B), as the pyrimidine tract is
located about 130 bases away from the 32P-labeled 5' end
(see Fig. 1). To accurately determine repair rates from the initial
slopes of repair curves, much shorter times were used for repair of
naked 5 S rDNA than for 5 S rDNA nucleosomes (Fig. 8B). The
area of each band was determined by peak deconvolution and used to
calculate the percent of CPDs removed at each site and after each
repair time. The repair rate was determined from the initial slope of
each repair curve, as shown in Fig. 8C for site
CC The X. borealis 5 S rRNA gene has been used as a model
system to study the relationship between RNA polymerase III
transcription and chromatin for many years. DNase I footprinting was
used to show that the majority of nucleosomes are precisely positioned after in vitro reconstitution onto a 256-bp long DNA
fragment containing the sea urchin 5 S rRNA gene (37). Mutation
analysis indicates that a region 20-30 bp on either side of the center of the core particle may contain the major elements responsible for
nucleosome positioning (38). More recently, it was demonstrated that
there is one dominant nucleosome position surrounded by minor positions, 10 bp apart, maintaining the identical rotational setting of
the 5 S rDNA (39, 40). In the present study, we chose a smaller
fragment (175 bp) containing 108 bp of 5 S rDNA gene (41) to limit the
number of molecules with different translational settings (Fig. 1).
Exonuclease III digestion indicates that the predominant nucleosome
positions on our fragment are with dyad positions near the
transcription start site (Fig. 2). Importantly, the rotational setting
of the 5 S rDNA relative to the histone surface (examined by DNase I
and hydroxyl radical footprinting) is in agreement with that previously
reported (10, 22). In a separate study, we also did extensive
experiments to analyze the effect of UV irradiation on 5 S nucleosome
positioning (10). After 500 J/m2 UV (i.e. the
dose used for these repair experiments), neither translational setting
nor rotational positioning showed any significant changes.
It was shown previously that NER of CPDs by human cell extracts is
suppressed in plasmid DNA containing reconstituted nucleosomes (42). In
that study, repair synthesis was required to detect DNA repair due to
the low repair efficiency of human cell extracts, and measurement of
repair at specific CPD sites was not possible. The robust DNA repair
activity of Xenopus oocyte nuclear extracts allowed us to
follow CPD removal at individual sites in the 5 S nucleosome. In
agreement with the data from human cell extracts (42), we also detect a
marked inhibition of NER at many sites in 5 S rDNA upon nucleosome
formation. Curiously, repair at some sites is not inhibited by
nucleosome formation (Figs. 5 and 6).
Recently, using the same in vitro system, we observed that
binding of transcription factor TFIIIA to 5 S rDNA severely inhibits repair in the 50-bp TFIIIA binding region (30). This inhibition was
limited to the 50-bp TFIIIA binding site (or internal control region),
as repair was equal to that of naked 5 S rDNA at CPD sites just outside
the ICR. In this study, however, slow repair of nucleosomal 5 S
rDNA was detected at most CPD sites throughout the fragment (Fig. 6).
This difference most likely reflects the much higher binding
specificity and affinity of TFIIIA for the internal control
region than that of the histone octamer for 5 S rDNA (10, 34).
Furthermore, it was shown that transcription of the 5 S rRNA gene does
not occur in our repair reactions (30). Therefore, our present results
reflect NER of the 5 S rRNA gene in the absence of polymerase III transcription.
In this report, we found that naked 5 S rDNA is repaired very
efficiently at most CPD sites in the Xenopus oocyte nuclear extract. At these sites, CPDs are almost completely removed after a 2-h
incubation (t1/2 values are <1 h). The few
exceptions (e.g. The average half-life of CPDs within the interior 125-bp domain of
nucleosomes was 4.8 h, whereas beyond this domain the average half-life dropped to 3.1 h. However, the striking variation of repair rates near the dyad of the nucleosome indicates that access of
CPDs to repair proteins in the Xenopus nuclear extracts does not follow the dynamic nucleosome model in the simplest form proposed by Polach and Widom (44, 45). In this model, CPD sites near the two
edges of the nucleosome should be far more accessible (by a factor of
100 to 1000) than CPD sites in the dyad region. Presumably, the
observed variations in repair rate reflect local histone-DNA interactions.
Comparison of repair rates at different CPD sites in the 5 S rDNA
nucleosome with the crystal structure indicates that three of the
slowly repaired CPD sites (+21CTTTC+25 and
CT+42 of the TS and site CC+53 of the NTS) are
in direct contact with the histone folds (1). However, other slowly
repaired CPD sites are not in direct contact with the histones, such
as Removal of histone N-terminal tails does not significantly change
the inhibition of NER by nucleosome assembly (Fig. 7). Similar findings
have been obtained with the activities of E. coli UV photolyase and T4 endo V on the 134-bp HISAT nucleosome (20). In
that study, it was found that photoreversal and cleavage of CPDs is
inefficient in nucleosomes compared with naked DNA, and removal of the
histone tails did not substantially enhance these activities. The role
of histone N-terminal tails in chromatin has been elusive. It was
recently proposed that in chromatin the N-terminal tails are engaged
primarily in protein-protein interactions rather than protein-DNA
interactions (36). In addition, the core histone tails were found to
have a repressive effect on transcription within oligonucleosomes (47).
Thus, it was not surprising that NER was unaffected by removal of the
histone tails in our study on mononucleosomes but may effect repair
within oligonucleosomes.
We also analyzed the correlation of NER with rotational setting in a
14-nt pyrimidine tract on the transcribed strand (Fig. 8). Repair at
all but one CPD site at the 3' end of this tract was very similar in 5 S nucleosomes and about 60% less than in naked 5 S rDNA after 2 h. This result indicates there is no correlation between rotational
setting and repair kinetics in the 5 S nucleosome, and CPDs facing
toward the histone surface are repaired with equal efficiency in the
Xenopus extract as CPDs facing outward. Alternatively, CPDs
at sites near the histone surface may force the DNA helix to rotate
outward at these sites. These results are in agreement with previous
work in this lab showing that CPDs are removed at nearly equal rates
from the inner and outer faces of the undamaged DNA helix in nucleosome
cores during the early, rapid phase of repair in human cells (18). One
possible explanation for this lack of correlation between DNA repair
and original rotational setting of the DNA helix is that nucleosomes
are actively disrupted before NER (e.g. see Ref. 48).
Clearly, this possibility is supported by the extensive evidence
showing nucleosome rearrangement during NER in intact cells
(reviewed in Refs. 4 and 6).
In conclusion, we found that (a) nucleosome assembly
inhibits repair by Xenopus oocyte nuclear extracts of the 5 S rDNA sequence at many CPD sites, (b) CPD removal at
specific sites varies markedly where some rapidly repaired sites are
located in the interior of the nucleosome, (c) removal of
histone tails does not enhance DNA repair efficiency in these
mononucleosomes, and (d) CPD removal rates in a 14-nt
pyrimidine tract do not correlate with the rotational setting of the
undamaged rDNA fragment assembled into the nucleosome.
We thank Drs. Eric J. Ackerman and Lilia
Koriazova for providing Xenopus oocyte nuclei and
critically evaluating this manuscript, Dr. R. Stephen Lloyd for
supplying purified T4 endo V, and Dr. Antonio Conconi for critical
discussions throughout this work.
*
This study was supported by National Institutes of Health
Grant ES02614 (NIEHS).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. Tel.: 509-335-6853;
Fax: 509-335-9688; E-mail: smerdon@mail.wsu.edu.
Published, JBC Papers in Press, May 19, 2000, DOI 10.1074/jbc.M002206200
The abbreviations used are:
bp, base pair(s);
CPD, cis-syn-cyclobutane pyrimidine dimer;
TS, transcribed
strand;
NTS, non-transcribed strand;
T4 endo V, T4 endonuclease V;
NER, nucleotide excision repair;
nt, nucleotide(s);
PMSF, phenylmethylsulfonyl fluoride;
CE, chicken erythrocyte.
Nucleotide Excision Repair of the 5 S Ribosomal RNA Gene
Assembled into a Nucleosome*
and
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
-32P]ATP (3000 Ci/mmol) used in this study was obtained from NEN Life Science
Products. SexAI and SalI were purchased from
Roche Molecular Biochemicals. T4 endo V was a generous gift from Dr.
R. S. Lloyd (University of Texas Medical Branch, Galveston, TX).
-32P]ATP
using T4 polynucleotide kinase (U. S. Biochemical Corp.). A second
restriction enzyme digestion (SalI for transcribed strand labeling and SexAI for non-transcribed strand labeling)
produced a single end-labeled DNA fragment containing 108 bp of the 5 S rRNA gene (see Fig. 1). The resulting 175-bp DNA fragment was recovered
from a 2% agarose gel using a QIAEXII gel extraction kit (QIAGEN Inc.)
and dissolved in 10 mM Tris-HCl, 1 mM EDTA, pH
8.0.
80 °C.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Schematic diagram of the 175-bp
SexAI-SalI 5 S rDNA fragment used in
this study. The thick arrow designates the location of
the 5 S rRNA gene, and the ovals are the two predominate nucleosome
formation sites found previously in larger fragments (34).
Vertical arrows (+7 and 3) denote the positions of the
dyad axis of these nucleosomes, and the numbers denote
positions relative to the 5 S rRNA gene transcription start site (+1).
The location of the 14-nt long pyrimidine tract is indicated by the
hatched box, and the open box indicates the
TFIIIA binding region ICR, internal control region.
View larger version (35K):
[in a new window]
Fig. 2.
Characterization of reconstituted 5 S rDNA
nucleosomes. A, representative DNA band shift gel used
to show the formation of the 5 S nucleosome. The 175-bp 5 S rDNA
fragment, end-labeled at both 5' ends, was irradiated with different UV
doses as indicated and subjected to in vitro reconstitution.
Samples were separated on native gels, as described under "Materials
and Methods." B, digestion products of 5 S rDNA fragments
and reconstituted nucleosomes labeled in the non-transcribed
strand. Naked DNA (D) or reconstituted nucleosomes
(N) were digested with 100 units of exonuclease III for 1.5 min (lanes 1 and 3) or 3 min (lanes 2 and 4) at 37 °C. For DNase I digestion, naked DNA was
incubated with 0.35 units for 1.5 (lane 5) or 3 min
(lane 6), and nucleosomes were incubated with 7 units for 1 (lane 7) or 2 min (lane 8). For hydroxyl radical
reactions, either 1.5% (lanes 9 and 11) or 3%
(lanes 10 and 12) H2O2
was used to react with Fe-EDTA to generate hydroxyl radicals (see
"Materials and Methods"). Numbers on the right denote
the most frequent cleavage sites on the reconstituted nucleosomes by
both DNase I and hydroxyl radicals. Numbers on the left
denote the three major exonuclease III blockage sites.
5' exonuclease that can be used to map the translational position of nucleosomes on DNA (27). This enzyme will pause at the edge
of nucleosomes and proceed more slowly into nucleosome core DNA with
~10-bp pauses (27). As shown in Fig. 2B, naked DNA was
quickly digested by exonuclease III into short fragments (lanes
1 and 2), whereas the 5 S rDNA nucleosomes were
digested much more slowly (lanes 3 and 4). A
major block to digestion occurred at position +65 ± 3 followed by
two (less prominent) bands at 10-base intervals from this band,
indicating the nucleosome core edge is at (or near) this position. This
observation indicates that the most prominent nucleosome core setting
spans bases 67 (5' end of fragment) to +65 in the 175-bp fragment.
This yields a 131-bp nucleosome core with a translational setting
closest to the position having a nucleosome dyad at 3 (shaded
oval in Fig. 1; Ref. 34).
46, 36, 25, 15, 5, +6, +17, +27, +37, +47, and
+57 (Fig. 2B, lanes 11 and 12). DNase
I cuts preferentially within 1 nucleotide (nt) of most of these same
nucleosome 5 S rDNA sites (Fig. 2B, lanes 7 and
8). We note that an intense DNase I cut site, but not
hydroxyl radical cut site, also occurs at 31, being strong in both
naked 5 S rDNA and the 5 S nucleosome (star in Fig.
2B, lanes 5-8). This reflects the strong
sequence specificity of DNase I (28). These results are in good
agreement with previous studies on the rotational setting of 5 S rDNA
in nucleosomes (22).
View larger version (122K):
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Fig. 3.
Representative gels showing repair of naked
DNA (D) and nucleosomes (N) in
Xenopus oocyte nuclear extracts. The 175-bp 5 S
rDNA fragment was end-labeled on either the transcribed strand
(left panel) or the non-transcribed strand (right
panel), irradiated with 500 J/m2, reconstituted into
nucleosomes, and incubated with extracts for different times (0, 1, 2, 3, or 4 h). After purification, DNA was cut with T4 endo V and
separated on DNA sequencing gels. The positions of the 5 S rRNA gene on
each strand are denoted by the thick solid arrows, and the
two major translational positions of 5 S nucleosomes shown in Fig. 1
are indicated by the ovals. Stars next to
left panel denote CPD sites
+21CTTTC+25 (top),
+54TTC+56 (middle), and
+58TCCC+61 (bottom) of the
transcribed strand used for Fig. 5.
View larger version (15K):
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Fig. 4.
Time course of overall CPD removal from the
transcribed strand (A) and non-transcribed strand
(B) of the 5 S rDNA fragment. The percentage of
intact (uncut) 175-base 5 S rDNA fragment at different repair times was
determined for each strand in naked DNA (D, 
) and
nucleosomes (N, 
) from gels such as shown in Fig. 3. Data
represent the mean ± 1 S.D. of three separate experiments.
View larger version (15K):
[in a new window]
Fig. 5.
Repair curves of three different CPD sites in
the transcribed strand of the 5 S rDNA fragment. CPD removal in
naked DNA (D) and nucleosomes (N) are expressed
as dashed ( ) and solid lines (),
respectively. Repair of CPDs in naked DNA was fast at most sites,
whereas repair of CPDs in nucleosomes could be much slower (site
+21CTTTC+25; top panel), somewhat
slower (site +54TTC+56; middle
panel), or almost as fast (site
+58TCCC+61; bottom panel) as naked
DNA. Data represent the mean ± 1 S.D. of four separate
experiments.
59TCTCCT54 of the TS and
+28CCC+30 of the NTS are repaired much more
slowly. This variation in site-specific repair does not correlate with
initial yields of CPDs at these sites (data not shown) and, therefore,
may reflect an influence by neighboring DNA sequence and/or local DNA
structure on damage recognition or removal.
View larger version (22K):
[in a new window]
Fig. 6.
Modulation of site-specific DNA repair by
nucleosome assembly. The t1/2 values of each
CPD site were determined from its corresponding repair curve (see Fig.
5). At each site, the solid and shaded
bars represent the values for naked DNA and nucleosomes,
respectively. Many bars are at mid-points of short
pyrimidine tracts that could not be completely resolved on the gel. The
locations of the 5 S rRNA gene and most prominent nucleosome are
indicated by the closed arrow and oval,
respectively. Data represent the mean of four separate
experiments.
28TTCC25 and
+21CTTTC+25 of the TS is fast in naked DNA but
very slow in nucleosomes. Thus, repair at CPD sites in 5 S rDNA appears
to be differentially modulated by nucleosome assembly.
67 to +65), repair of the histone tail-depleted nucleosomes is very similar to that of intact 5 S rDNA nucleosomes (compare + and trypsin lanes). Similar
results were obtained for CPDs in the 5' half of the fragment (data not
shown). Therefore, the histone tails in these mononucleosomes must play
only a minor role in the modulation of NER in the 5 S rDNA
nucleosome.
View larger version (72K):
[in a new window]
Fig. 7.
Effect of removing histone tails on the
repair of nucleosomes. A, representative SDS protein
gel showing the results of a trypsin digestion of CE core particles.
B, representative nucleoprotein gel indicating the extent of
nucleosome formation on the 5 S rDNA fragment with complete and
tailless histones from CE core particles. C, representative
gel comparing repair of CPD sites in the transcribed strand in naked
DNA (D), intact nucleosomes (N , trypsin), and
nucleosomes without histone tails (N+, trypsin). Data were
taken as described for Fig. 3.
19 (arrow in Fig. 8B). To
minimize the influence of DNA sequence on the repair rates, the ratios
of the slopes for nucleosomes and naked DNA
(mN/mD) were plotted
versus CPD location (Fig. 8D). With the possible
exception of one site (TC14), no correlation exists
between the rotational setting of CPD sites on the core histone surface
and NER rates (Fig. 8D). The TC14 site is at
the 3' end of the tract facing away from the histone surface and has
the highest value of mN/mD
(0.58 ± 0.08). However, the
mN/mD ratio of the other 12 CPD
sites is very similar (~60% inhibition). For example, the mN/mD values for sites
CC19 (facing toward the histone surface) and
TC25 (facing away from the histone surface) are 0.31 ± 0.09 and 0.40 ± 0.08, respectively. The apparent small
modulation of relative repair rates observed in Fig. 8D is
not significant.
View larger version (24K):
[in a new window]
Fig. 8.
Relationship between DNA repair and
rotational setting of a 14-nt-long pyrimidine tract (see Fig. 1).
A, sequence of the 14-nt pyrimidine tract in 5 S rDNA
fragment. Stars represent sites farthest away from the
histone surface, and the triangle indicates the site closest
to histone surface in the undamaged 5 S rDNA fragment.
Numbers above the sequence denote nt from the transcription
start site of the 5 S rRNA gene. B, similar experiments as
described in Fig. 3 were performed with both naked DNA and nucleosomes,
where different incubation times (denoted above each lane)
were used to optimize analysis. C, time course of repair of
site CC 19 (denoted by the arrow in panel
B) determined from the band intensity following different repair
times. Two slopes (mD and mN)
were obtained after linear regression analysis of the data for naked
DNA () and nucleosomes (). D, the ratio of the two
slopes (mN/mD) at each CPD site
in the 14-nt-long pyrimidine tract (plotted as location from the
transcription start site of the 5 S rRNA gene).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
59TCTCCT54 in
the TS where t1/2 = 4.8 h) may be due to the
effect of DNA sequence on repair (43). Assembly of 5 S rDNA into
nucleosomes generally caused inhibition of DNA repair. Several of the
very slow repair sites are in the interior 125 bp of the nucleosome
core (65 to +60) (Fig. 6). Over 50% of the CPD sites in this region
have t1/2 values greater than 4 h, with
extremely slow repair occurring at sites
59TCTCCT54,
28TTCC25, and
+21CTTTC+25 of TS and CC+15,
+43TCTC+46, and CC+53 of NTS
(t1/2 > 8 h). In contrast, CPDs at five sites
in this region (10CCT8,
TT7, +17CCCT+20, and
+38TCT+40 of NTS and CT+32 of TS)
are repaired at almost the same rate as in naked DNA. Beyond +60, 10 of
14 CPD sites have t1/2 values less than 4 h
(i.e. approaching repair rates of naked DNA). The remaining
CPD sites are more slowly repaired (t1/2 values of 4 to 7 h), and these sites may reflect multiple translational settings of the histone octamer.
40TCTTCC35 and
28TTCC25 of the TS and sites
CC+15, TC+36, and
+43TCTC+46 of the NTS. More surprisingly,
almost all of the fast repair sites make direct contact with histone
folds in the crystal (1). These are sites CT+32 and
+58TCCC+61 of the TS and sites
10CCT8, +17CCCT+20,
and +38TCT+40 of the NTS. These may represent
sites that locally destabilize the nucleosome core or reduce the
dominant constraint(s) on DNA by core histones (46), rendering the
interior of these nucleosomes more accessible to repair enzymes.
ACKNOWLEDGEMENTS
FOOTNOTES
Present address: Dept. of Molecular and Cellular Biology, Harvard
University, 16 Divinity Ave., Cambridge, MA 02138.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
1.
Luger, K.,
Mader, A.,
Richmond, R.,
Sargent, D.,
and Richmond, T.
(1997)
Nature
389,
251-260
2.
van Holde, K. E.
(1989)
Chromatin
, Springer-Verlag New York Inc., New York
3.
Luger, K.,
and Richmond, T.
(1998)
Curr. Opin. Struct. Biol.
8,
33-40
4.
Smerdon, M. J.,
and Thoma, F.
(1998)
in
DNA Damage and Repair: Biochemistry, Genetics, and Cell Biology
(Nickoloff, J. A.
, and Hoekstra, M. F., eds)
, pp. 199-222, Humana Press Inc., Totowa, NJ
5.
Wolffe, A. P.
(1998)
Chromatin: Structure and Function
, 3rd Ed.
, Academic Press, Inc., San Diego, CA
6.
Smerdon, M. J.,
and Conconi, A.
(1999)
Prog. Nucleic Acid Res. Mol. Biol.
62,
227-255
7.
Gale, J. M.,
Nissen, K. A.,
and Smerdon, M. J.
(1987)
Proc. Natl. Acad. Sci. U. S. A.
84,
6644-6648
8.
Brown, D. W.,
Libertini, L. J.,
Suquet, C.,
Small, E. W.,
and Smerdon, M. J.
(1993)
Biochemistry
32,
10527-10531
9.
Pehrson, J. R.,
and Cohen, L. H.
(1992)
Nucleic Acids Res.
20,
1321-1324
10.
Liu, X.,
Mann, D. B.,
Suquet, C.,
Springer, D. L.,
and Smerdon, M. J.
(2000)
Biochemistry
39,
557-566
11.
Friedberg, E. C.,
Walker, G. C.,
and Siede, W.
(1995)
DNA Repair and Mutagenesis
, American Society for Microbiology, Washington, D. C.
12.
Cadet, J.,
Anselmino, C.,
Douki, T.,
and Voituriez, L.
(1992)
J. Photochem. Photobiol. B Biol.
15,
277-298
13.
Wang, C. I.,
and Taylor, J. S.
(1991)
Proc. Natl. Acad. Sci. U. S. A.
88,
9072-9076
14.
Kim, J. K.,
Patel, D.,
and Choi, B. S.
(1995)
Photochem. Photobiol.
62,
44-50
15.
McAteer, K.,
Jing, Y.,
Kao, J.,
Taylor, J. S.,
and Kennedy, M. A.
(1998)
J. Mol. Biol.
282,
1013-1032
16.
Smerdon, M. J.
(1989)
in
DNA Repair Mechanisms and Their Biological Implications in Mammalian Cells
(Lambert, M. W.
, and Laval, J., eds)
, pp. 271-294, Plenum Publishing Corp., New York
17.
Lan, S. Y.,
and Smerdon, M. J.
(1985)
Biochemistry
24,
7771-7783
18.
Jensen, K. A.,
and Smerdon, M. J.
(1990)
Biochemistry
29,
4773-4782
19.
Wellinger, R. E.,
and Thoma, F.
(1997)
EMBO J.
16,
5046-5056
20.
Schieferstein, U.,
and Thoma, F.
(1998)
EMBO J.
17,
306-316
21.
Kosmoski, J. V.,
and Smerdon, M. J.
(1999)
Biochemistry
38,
9485-9494
22.
Hayes, J. J.,
Clark, D. J.,
and Wolffe, A. P.
(1991)
Proc. Natl. Acad. Sci. U. S. A.
88,
6829-6833
23.
Oda, N.,
Saxena, J. K.,
Jenkins, T. M.,
Prasad, R.,
Wilson, S. H.,
and Ackerman, E. J.
(1996)
J. Biol. Chem.
271,
13816-13820
24.
Mann, D. B.,
Springer, D. L.,
and Smerdon, M. J.
(1997)
Proc. Natl. Acad. Sci. U. S. A.
94,
2215-2220
25.
Libertini, L. J.,
Ausio, J.,
van Holde, K. E.,
and Small, E. W.
(1988)
Biophys. J.
53,
477-487
26.
Ausio, J.,
Dong, F.,
and van Holde, K. E.
(1989)
J. Mol. Biol.
206,
451-463
27.
Neubauer, B.,
and Horz, W.
(1989)
Methods Enzymol.
170,
630-644
28.
Lutter, L. C.
(1989)
Methods Enzymol.
170,
264-269
29.
Tullius, T. D.,
Dombroski, B. A.,
Churchill, M. E.,
and Kam, L.
(1987)
Methods Enzymol.
155,
537-558
30.
Conconi, A.,
Liu, X.,
Koriazova, L.,
Ackerman, E.,
and Smerdon, M. J.
(1999)
EMBO J.
18,
1387-1396
31.
Sambrook, J.,
Fritsch, E. F.,
and Maniatis, T.
(1989)
Molecular Cloning: A Laboratory Manual
, 2nd Ed.
, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
32.
Li, S., Waters, R., and Smerdon, M. J. (2000) Methods: A
Companion to Method in Enzymol., in press
33.
Bohr, V. A.,
Smith, C. A.,
Okumoto, D. S.,
and Hanawalt, P. C.
(1985)
Cell
40,
359-369
34.
Panetta, G.,
Buttinelli, M.,
Flaus, A.,
Richmond, T. J.,
and Rhodes, D.
(1998)
J. Mol. Biol.
282,
683-697
35.
Wood, R. D.,
Robins, P.,
and Lindahl, T.
(1988)
Cell
53,
97-106
36.
Hansen, J. C.,
Tse, C.,
and Wolffe, A. P.
(1998)
Biochemistry
37,
17637-17641
37.
Simpson, R. T.,
and Stafford, D. W.
(1983)
Proc. Natl. Acad. Sci. U. S. A.
80,
51-55
38.
FitzGerald, P. C.,
and Simpson, R. T. V.
(1985)
J. Biol. Chem.
260,
15318-15324
39.
Dong, F.,
Hansen, J. C.,
and van Holde, K. E.
(1990)
Proc. Natl. Acad. Sci. U. S. A.
87,
5724-5728
40.
Meersseman, G.,
Pennings, S.,
and Bradbury, E. M.
(1991)
J. Mol. Biol.
220,
89-100
41.
Wolffe, A. P.
(1994)
J. Cell Sci.
107,
2055-2063
42.
Wang, Z. G.,
Wu, X. H.,
and Friedberg, E. C.
(1991)
J. Biol. Chem.
266,
22472-22478
43.
Pfeifer, G. P.
(1997)
Photochem. Photobiol.
65,
270-283
44.
Polach, K. J.,
and Widom, J.
(1995)
J. Mol. Biol.
254,
130-149
45.
Polach, K. J.,
and Widom, J.
(1996)
J. Mol. Biol.
258,
800-812
46.
Hayes, J. J.,
Bashkin, J.,
Tullius, T. D.,
and Wolffe, A. P.
(1991)
Biochemistry
30,
8434-8440
47.
Chirinos, M.,
Hernandez, F.,
and Palacian, E.
(1998)
Biochemistry
37,
7251-7259
48.
Meijer, M.,
and Smerdon, M. J.
(1999)
Bioessays
21,
596-603
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