(Received for publication, October 2, 1996, and in revised form, January 3, 1997)
From the Laboratory of Molecular Pharmacology, Division of Basic Sciences, NCI, National Institutes of Health, Bethesda, Maryland 20892
Abasic sites and deamination of cytosine to
uracil are probably the most common types of endogenous DNA damage. The
effects of such lesions on DNA topoisomerase I (top1) activity were
examined in oligonucleotides containing a unique top1 cleavage site.
The presence of uracils and abasic sites within the first 4 bases immediately 5 to the cleavage site suppressed normal top1 cleavage and
induced new top1 cleavage sites. Uracils immediately 3
to the cleavage
site increased cleavage and produced a camptothecin mimicking effect. A
mismatch with a bulge or abasic sites immediately 3
to the top1
cleavage site irreversibly trapped top1 cleavable complexes in the
absence of camptothecin and produced a suicide cleavage complex. These
results demonstrate that top1 activity is sensitive to physiological,
environmental, and pharmacological DNA modifications and that top1 can
act as a specific mismatch- and abasic site-nicking enzyme.
Abasic sites are the most common endogenous lesions found in DNA, with an estimated 10,000 lesions per human cell per day (1). They arise spontaneously by hydrolysis of the glycosidic bond primarily to purine bases. They are also produced during the course of excision repair of base damage due to oxidation or alkylation during normal metabolism and during the repair of exogenous damage by ionizing radiation, environmental carcinogens, or drugs used in cancer chemotherapy. Ubiquitous uracil N-glycosylase also processes uridines in DNA to abasic sites (for review, see Refs. 1-3). The occurrence of uracil, generated from the spontaneous deamination of cytosine, has been estimated at 100-500 per human cell per day (1).
Mammalian DNA topoisomerases (including
top11) are ubiquitous enzymes involved in
multiple processes, including DNA replication, transcription, and
illegitimate recombination (4). top1 acts as a monomer, binds to duplex
DNA, and creates transient single-strand breaks via the formation of
covalent adducts between the 3-phosphate of the cleaved strand and a
tyrosyl residue of the enzyme. These intermediates are commonly
referred to as cleavable complexes (4-6). Under physiological
conditions, top1 catalyzes the religation of the 5
-hydroxyl group of
the broken DNA. Camptothecin (CPT), a potent anticancer agent, inhibits
the religation step and transforms transient top1-linked DNA breaks
into more persistent breaks. Although the intimate mechanism of action
of CPT and its derivatives is not totally resolved, CPT probably forms
a ternary complex with the enzyme and the DNA (5, 7, 8). In the cell,
cleavable complexes can be converted into permanent DNA damage during
replication and transcription (9, 10). These irreversible reactions
have been referred to as "suicide reactions" because top1-cleavable complexes cannot religate their normal acceptor under these conditions (11, 12). top1 can then promote illegitimate recombination with various
double-stranded DNAs bearing a 5
-hydroxyl terminus (11-15). All of
these events may be responsible for cell death, converting top1 from an
essential enzyme to a cell poison (5, 7).
In this study, we examined the effect of uracil incorporation and abasic site generation on top1 cleavage activity and demonstrate that these frequent DNA lesions can, depending on their location relative to the top1 cleavage site, inhibit the catalytic activity of the enzyme or trap top1 on DNA. Recently, in vitro cleavage of another mammalian topoisomerase, the type II enzyme, was found to be enhanced by the introduction of abasic sites into DNA substrates (16).
Oligonucleotides were purchased from
Midland Certified Reagent Co. (Midland, TX).
-32P-cordycepin 5
-triphosphate was purchased from New
England Nuclear (Boston, MA). Polyacrylamide was purchased from
Bio-Rad, Inc. (Richmond, CA). Calf thymus type I DNA topoisomerase was
purchased from Life Technologies, Inc. CPT was provided by Drs. Wani
and Wall (Research Triangle Institute, Research Triangle Park, NC). 10 mM aliquots of CPT were stored at
20 °C, thawed, and
diluted to 1 mM in dimethyl sulfoxide just before use.
The scissile
(upper) strand of the duplex oligonucleotides (see Figs. 1, 2, 3, 4, 5) were
labeled with -32P-labeled cordycepin using terminal
deoxynucleotidyl transferase (Stratagene, La Jolla, CA) as described
previously (15). The reaction mixture was subsequently centrifuged
through a G25 Sephadex column to remove the excess of unincorporated
cordycepin. Labeled scissile strand was then annealed to the same
concentration of unlabeled lower strands containing uracils at
different positions, or a cytosine bulge as described in Fig.
4A (15).
Preparation of Oligonucleotides Containing Abasic Sites
Double-stranded oligonucleotides containing uracils at
different positions were treated for 2 h at 30 °C with 1 unit
(1 µl) of uracil DNA glycosylase (Life Technologies, Inc.) to create an abasic site at the equivalent position (31). The buffer used was the
same as for annealing (10 mM Tris·HCl, pH 7.8, 100 mM NaCl, 1 mM EDTA). The reaction mixture was
then centrifuged through a G25 Sephadex column and used in the top1
reactions. The efficiency of abasic site formation by uracil DNA
glycosylase was verified by the nicking of over 80% of the
oligonucleotide at the abasic site in the presence of 10 mM
NaOH (1 h at 25 °C) (see Fig. 5B, lane d). The
tetrahydrofuran oligonucleotide used in Fig. 6 was purchased from
Midland Certified Reagent Co.
top1 Reactions
DNA substrates (approximately 50 fmol/reaction) were incubated with 5 units of top1 for 15 min at 25 °C with or without CPT in standard reaction buffer (10 mM Tris·HCl, pH 7.5, 50 mM KCl, 5 mM MgCl2, 0.1 mM EDTA, 15 µg/ml bovine serum albumin). Reactions were stopped by adding either sodium dodecyl sulfate (SDS) (final concentration 0.5%) or NaCl (unless otherwise indicated, 0.5 M for 30 min at 25 °C followed by addition of 0.5% SDS). Kinetics of reversal were performed by adding NaCl (0.25 M final concentration) to the reactions and incubating the samples at 10 °C for indicated times. Time-course reactions were stopped with 0.5% SDS.
Gel Electrophoresis and Analysis of Cleavage Products3.3 volumes of Maxam Gilbert loading buffer (98% formamide, 0.01 M EDTA, 1 mg/ml xylene cyanol, and 1 mg/ml bromophenol blue) were added to the reaction mixtures before loading. 16% denaturing polyacrylamide gels (7 M urea) were run at 40 V/cm at 50 °C for 2-3 h and dried on 3MM Whatman paper sheets. Imaging and quantitations were performed using a PhosphorImager (Molecular Dynamics, Sunnyvale, CA).
The substrates used in these studies were derived from a Tetrahymena oligonucleotide (17) containing a top1 cleavage site where adenine in +1 position on the scissile (upper) strand was changed to a guanine to increase the effect of camptothecin and its derivatives (Fig. 1A) (8). We first investigated the effect of uracil incorporation at various positions in the nonscissile (lower) strand on the DNA cleavage/religation equilibrium induced by top1 in the presence or absence of CPT.
Cleavage activity of top1 was significantly altered, depending on the
uracil position. As shown in Fig. 2, three different effects were observed: (i) suppression of top1 cleavage when uracil was
incorporated at positions 3,
2, and
1, and to a lesser extent at
position
4. This suppression was observed even in the presence of 10 µM CPT. These results show that uracil misincorporation within the 4 bases immediately upstream from the top1 site (5
to the
top1 cleavage site) suppresses DNA cleavage. Thus, modifications of DNA
in this region can markedly alter top1 catalytic activity. (ii)
Enhancement of top1 cleavage in the absence of CPT at the preexisting
site was observed when uracil was incorporated at either the
6,
5,
or +1 position (Fig. 2, compare lanes 2 for these positions
and lanes 2 for the controls). This enhancement was
7-10-fold compared with control, and this effect was still observed
for positions as far as
7 and
8 from the cleavage site (data not
shown). In all cases, cleavage was reversible upon addition of 0.5 M NaCl (Fig. 2, lanes 3 and 5). (iii)
Induction of a new top1 cleavage site was observed when uracils were
incorporated at positions
2 and
1 (Fig. 2A, white
arrow). In the case of the
2 mismatch, the new top1 cleavage
site was independent of CPT and was located immediately upstream from
the mismatch, which is consistent with the enhancement produced by a
mismatch at the +1 position. These data indicate that base mismatches
can trap top1 cleavable complexes (18).
Modified oligonucleotides were used
to investigate the effect of abasic sites at given positions on the
top1 cleavage activity in the presence or absence of CPT. Depending on
the position of the abasic site, top1 cleavage activity was
differentially affected (Fig. 3). Abasic sites at
positions 4,
3,
2, and
1 suppressed top1 cleavage at the normal
site. New sites were also induced immediately upstream from the abasic
site when the abasic site was at position
5,
4, or
2. top1
cleavage was enhanced (4-5-fold) in the absence of CPT when the abasic
site was at positions
6,
2, and +1. This enhancement was associated
with an inhibition of religation when the abasic site was at position
2 or +1. This can be seen in Fig. 3 as a persistent cleavage band
(60-80% of the initial cleavage) after addition of salt (Fig. 3,
compare lanes 4 and 5 and lanes 2 and
3). It should be noted that the persistent site observed
with the oligonucleotide containing an abasic site at position
2
corresponds to an abasic site immediately downstream from the cleavage
site. The results observed both with the abasic sites at positions +1
and
2 indicate that the presence of an abasic site immediately
downstream from a top1 cleavage site enhances cleavage in the absence
of CPT by inhibiting DNA religation and induces suicide-type
reaction.
Enhancement of top1 cleavage in the absence of CPT was also observed using an oligonucleotide containing a displaced loop (bulge) next to the cleavage site on the nonscissile strand (Fig. 4A). Using different conditions of reversal, such as increased concentration of sodium chloride (N) or proteinase K (P) or heat treatment (H), we found that top1 cleavage persisted under these conditions. Using this mispair loop substrate, CPT had no further effect. With the control substrate, CPT-induced DNA cleavage was completely reversed by salt, proteinase K, or heat (Fig. 4B, left). Together, these results demonstrate that top1 can cleave efficiently DNA with a bulge but fails to religate the DNA, probably because of the stretching out of the loop and separation of the acceptor DNA from the top1. This would generate a suicide-type reaction.
Effects of Mismatches and Abasic Sites at the +1 Position of the Scissile Strand on top1 Cleavage ActivityBecause the guanine at position +1 on the scissile strand has been shown to increase the specificity of CPT derivatives for top1 cleavable complexes (19), we tested the effect of an uracil or an abasic site at this position. Uracil mismatch (U:C) or wobble base pair (U:G) increased top1 cleavage in the absence of CPT 8- and 7-fold, respectively (Fig. 5A, lanes 11, 12, 17, and 18). On the other hand, when an adenine was incorporated at the +1 position on the lower strand, leading to a U:A base pairing, no cleavage difference was noted as compared with the control and CPT was still active (Fig. 5A, lanes 5 and 6). All corresponding substrates containing an abasic site also increased top1 cleavage in the presence or the absence of CPT (Fig. 5A, lanes 8, 9, 14, 15, 20, and 21). Reversal of cleavage was studied in the presence of 0.25 M NaCl to investigate the irreversible nature of the cleavage. The reaction rate of the top1-mediated religation process was decreased for the control oligonucleotide in the presence of 10 µM CPT, but reversal was complete after 15 min incubation (Fig. 5B), which is consistent with previous findings indicating that CPT reversibly inhibits the religation step of the top1 catalytic reaction (12, 20, 21). Uracil incorporation at the +1 position on the scissile strand did not affect the religation step in the absence of CPT, and reversal was complete after 5 min. In contrast, the presence of an abasic site at the same position inhibited the reversal of top1 cleavage, even when longer reversal times were used (Fig. 5B, right panel, arrow), suggesting the formation of a suicide product.
We further tested the effect of the abasic site at the +1
position by using a modified oligonucleotide synthesized with a tetrahydrofuran abasic site analogue at this position (Fig.
6A). The same irreversible trapping of top1
was observed in the absence or presence of camptothecin (Fig.
6B). Together, these results indicate that the presence of
an abasic site immediately 3 to the top1 cleavage (position +1)
generates a suicide product.
The present study demonstrates that uracil incorporation, DNA
mismatches, and abasic sites can have profound and contrasting effects
on top1 activity, depending on their position relative to the top1
cleavage site. Modifications within the first 4 bases immediately
upstream of the cleavage site (positions 1 to
4) generally
suppressed top1 cleavage, whereas modifications immediately downstream
(position +1) generally trapped top1 cleavable complexes.
Uracil incorporation can result in true mismatches (C:U, T:U) or
abnormal base pairs (G:U or A:U). Yeh et al. (18) have reported that the mammalian all-type mismatch nicking enzyme forms a
cleavable complex with the 3-DNA terminus 5
to the eight possible types of DNA mismatches. They found that this mismatch nicking activity
was in fact an intrinsic activity of top1 (18). Nash and Robertson (22)
have also demonstrated that
-Int topoisomerase specifically cleaves
heteroduplex attachment sites containing mismatches. Consistent with
these results, we found that the true mismatch U:C (Fig. 5A)
resulted in enhanced top1 cleavage activity. However, we also found the
same enhancing effect when base pairing was retained as in the case of
the wobble base pairs G:U (Fig. 2B) or U:G (Fig.
5A). However, normal base pairing as in A:U had no effect on
the enzyme activity (data not shown). These results demonstrate that
abnormal DNA structure at the +1 position, immediately 3
to the top1
cleavage site, is more important than the presence of uracil per
se at this position. The study of Yeh et al. (18) also
demonstrated the influence of DNA sequence immediately flanking the
mismatch but did not investigate mismatches at specific sites relative
to the top1 cleavage sites. Our study suggests that the top1 mismatch
nicking activity exhibits selectivity for base mismatches immediately
downstream of the preexisting top1 cleavage site: primarily at the +1
position and to a lesser extent at the +2 position because no cleavage
enhancement was observed for mismatches at positions
1,
2, or
3
(23). This indicates that top1 can act as a mismatch-nicking enzyme
only at limited sites on the DNA and that such sites are primarily
determined by the enzyme. We also show for the first time that a
mispaired single-stranded loop (bulge) immediately 3
to the cleavage
site leads to an irreversible cleavage complex.
The effects of uracil incorporation 5 to the cleavage site depended on
its position and on the structure of the resulting base pair (true
mismatches C:U or T:U, wobble base pair G:U, or normal A:U base pair).
When uracil was close to the top1 cleavage site (positions
1,
2, or
3) and resulted in T:U or C:U mismatches, top1 cleavage was
suppressed. The lack of suppression by uracil incorporation at position
4 might be due to an insignificant structural modification of the DNA
because it resulted in an A:U base pair. When uracil was further
upstream, at positions
6,
7, or
8, also resulting in A:U base
pairs, top1-induced DNA cleavage was stimulated. Thus, major groove
contacts in this region upstream from the cleavage site appear to be
critical for enzyme activity (23-26). This result is consistent with a
previous study (27) showing that cytosine methylation at position
3
on the scissile strand suppressed top1 cleavage, whereas no such
suppression was observed at position
4. Together these observations
indicate that both base pairing and major groove structure at each
position upstream from the top1 cleavage site are critical for enzyme
activity (23-26).
This is the first report of a top1-abasic site nicking activity that is
strongly dependent on the specific position of the abasic site relative
to the top1 cleavage site. A recent study of Osheroff and coworkers
(16) showed that mammalian topoisomerase II exhibits nicking activity
in DNA containing random chemically generated abasic sites. However, no
such activity was demonstrated for top1 in their conditions using
plasmid DNA. This could be attributed to the critical importance of the
position of the abasic site relative to the top1 cleavage sites. Thus,
the enhancing effects could have been masked by the suppressive effects
in their global analysis using a large DNA fragment. An abasic site
immediately 5 (position +1 on the scissile or uncleaved strand) to the
cleavage site trapped irreversible top1-cleavable complexes (suicide
products). Enhanced top1 cleavage in the absence of camptothecin was
also observed with abasic sites at the +2 position and to a lesser extent at the +3 position. However, enhancement was less pronounced and
cleavable complexes were more reversible than for the abasic sites at
position +1. This is a camptothecin-mimetic effect (5). Under these
conditions, the religation step afterward is hindered by the abasic
site. This could be interpreted as a requirement for base pairing
immediately downstream from the top1-DNA linkage to align the cleaved
strand for religation.
The presence of abasic sites had opposite (suppressive) effects when
they were located 5 to the top1 cleavage site, from position
1 to
position
4. This observation is consistent with the requirement of
optimum enzyme-DNA contact with a tetramer oligonucleotide immediately
upstream from the top1 site (23). Evidence for the close interaction of
mammalian top1 with the 4 base pairs immediately upstream from the top1
cleavage site has already been suggested from the uracil incorporation
data discussed above and from previous studies demonstrating that base preferences for top1 cleavage sites is strongest for the
1,
2,
3,
and
4 positions (19, 21, 28, 29).
As indicated in the introduction, spontaneous formation of uracil bases by hydrolysis of cytosines and abasic sites by depurination, alkylation, or glycosylase action are among the most frequent DNA lesions, with thousands of such lesions formed daily in any given human cell (1). Loop mispairs have been implicated in mismatch repair (3). The existence of top1 cleavable complexes associated with such lesions has not been demonstrated in vivo to date except for the observation of Yeh et al. (18) that top1 may correspond to the all-type mismatch nicking enzyme. Assuming that damaged DNA can trap cleavable complexes, several scenarios can be envisaged. First, trapping of top1 cleavable complexes may play a role in DNA repair by tagging the mismatches, recruiting DNA repair enzymes, and/or arresting transcription and replication, and subsequently preventing errors. This situation might be analogous to poly(ADP-ribose) polymerase, which binds to single-strand breaks and may initiate DNA repair (30). Alternatively, top1 trapping may exert lethal effects, as in the case of top1 cleavable complexes trapped by camptothecin (5). This may represent a way for cells with damaged DNA to be tagged for programmed cell death. However, a fraction of the damaged cells may survive, and the irreversible (suicide), as well as the reversible cleavable complexes, as in the case of camptothecin, may lead to DNA recombinations (15).