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Molecular and Cellular Biology, January 2000, p. 173-180, Vol. 20, No. 1
0270-7306/0/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Stabilizing Effects of Interruptions on
Trinucleotide Repeat Expansions in Saccharomyces
cerevisiae
Michael L.
Rolfsmeier and
Robert S.
Lahue*
Eppley Institute for Research in Cancer and
Allied Diseases, University of Nebraska Medical Center, Omaha,
Nebraska 68198-6805
Received 3 August 1999/Returned for modification 15 September
1999/Accepted 24 September 1999
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ABSTRACT |
In most trinucleotide repeat (TNR) diseases, the primary factor
determining the likelihood of expansions is the length of the TNR. In
some diseases, however, stable alleles contain one to three base pair
substitutions that interrupt the TNR tract. The unexpected stability of
these alleles compared to the frequent expansions of perfect TNRs
suggested that interruptions somehow block expansions and that
expansions occur only upon loss of at least one interruption. The work
in this study uses a yeast genetic assay to examine the mechanism of
stabilization conferred by two interruptions of a 25-repeat tract.
Expansion rates are reduced up to 90-fold compared to an uninterrupted
allele. Stabilization is greatest when the interruption is replicated
early on the lagging strand, relative to the rest of the TNR. Although
expansions are infrequent, they are often polar, gaining new DNA within
the largest available stretch of perfect repeats. Surprisingly,
interruptions are always retained and sometimes even duplicated,
suggesting that expansion in yeast cells can proceed without loss of
the interruption. These findings support a stabilization model in which
interruptions contribute in cis to reduce hairpin formation during TNR replication and thus inhibit expansion rates.
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INTRODUCTION |
Trinucleotide repeat (TNR)
instability has been found in more than 12 human neurological diseases
that have many common genetic traits (1, 7, 18). One of the
most important predictors of TNR expansions is the length of the
triplet tract. In normal populations, the TNR is highly polymorphic but
relatively short. In affected individuals the TNR is expanded anywhere
from 5 to 2,000 repeats, depending on the disease locus (1, 7,
18). Not only does expansion often lead to disease but longer
repeats are also further destabilized, expanding with even higher
frequency upon subsequent transmissions. The cutoff between short,
stable alleles and long, unstable alleles has been termed the threshold (1, 7, 18). Once a threshold of about 35 repeats is reached, the likelihood of expansion in the next generation is greatly increased.
The purity of the TNR tract also influences its mutability. There are
three examples of TNR diseases in which most normal, stable alleles
contain one to three point mutations, or interruptions, interspersed
within the perfect repeat tract. SCA1 (spinocerebellar ataxia type 1 gene) contains CAT interruptions in a CAG tract (2), the CGG tract of the fragile X syndrome gene
FMR1 is punctuated with AGGs (3, 9, 13, 25), and
CAAs are dispersed through the CAG tract of SCA2 (10,
21, 23). About 1% of normal Friedreich's ataxia alleles have
five to eight GAGGAA hexanucleotide interruptions within a
GAA tract (17). In contrast, expanded alleles of these genes
have fewer or no interruptions. This correlation has led to the
suggestion that one or more interruptions must be lost before expansion
can occur (2, 3, 9, 10, 13, 22, 25). The most direct test of
this hypothesis would be to look at expansions that arise directly from
interrupted alleles. However, it has not been possible to address this
question directly owing to the lack of such events in humans.
Molecular models for the stabilizing influence of
interruptions include the idea that they provide an anchoring
sequence which helps keep the two strands of the duplex properly
aligned to prevent replicational slippage (19, 26).
Alternatively, interruptions may reduce the thermodynamic stability of
DNA hairpins that are thought to be important intermediates in the
expansion process (5, 19, 21). Another possibility is that
interruptions stabilize TNRs by breaking up the perfect repeat
stretches into smaller, subthreshold lengths. Expansions would occur
only if the perfect repeat regions can lengthen to achieve the
threshold, as has been suggested for fragile X (3, 9, 22,
25). In vitro, interruptions have been shown to decrease
formation of slipped-strand DNA (S-DNA) structures and also to limit
the number of different S-DNA isomers (19), which is
consistent with the idea that interruptions somehow physically
demarcate the positions where perfect repeats start and stop.
Using a yeast genetic assay, we were able to test these models. Our
results support the idea that interruptions in yeast can help prevent
the formation of hairpin DNA intermediates thought to be important for
the expansion process.
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MATERIALS AND METHODS |
Strains.
Escherichia coli DH5
[endA1
hsdR17 (rK
mK+)] supE44 thi-1 recA1 gyrA
(Nalr) relA1 
(lacI ZYA-argF)
U169 deoR)] was used for plasmid construction of the
interrupted TNR repeats and large-scale plasmid preparations. The
Saccharomyces cerevisiae strain used was MW 3317-21A
(MAT trp1 ura3-52 ade2 ade8 hom3-10 his3-KpnI met4
met13) (11). TNR-containing plasmids were directed to
integrate at LYS2 by Bsu36I digestion of the
appropriate plasmids. The linearized plasmids were then integrated via
lithium acetate transformation (24). Single integration of
the TNR sequence at LYS2 was confirmed by Southern
hybridization by using a 1.1-kb fragment of LYS2 as the probe sequence.
Plasmid constructs.
All plasmids were constructed using the
pBL94 vector (16), which contains the URA3 gene
driven by the Schizosaccharomyces pombe adh1 promoter, with
a unique SphI site separating the two elements. Variants of
pBL94 containing interrupted TNR sequences were generated by annealing
5'-phosphorylated complementary oligonucleotides as follows:
oligonucleotides were melted 10 min at 90°C, allowed to anneal by
cooling to 37°C for 40 min, and then held at 25°C for 10 min.
Annealed oligonucleotides were cloned into the SphI site of
pBL94. To generate the 5' interrupted sequence, oBL 199 [5'-(CTG)6 ATGATG(CTG)17 CATG 3']
was annealed to oBL 198 [5'-(CAG)17 CATCAT(CAG)6 CATG-3']. The 3' interruption was
created by pairing oBL 197 [5' (CTG)17
ATGATG(CTG)6 CATG-3'] with oBL 196 [5'-(CAG)6 CATCAT(CAG)17 CATG-3'].
The centrally interrupted sequence was derived from oBL 220 [5'-(CTG)11 ATGATG(CTG)12 CATG-3']
and oBL 219 [5' (CAG)12
CATCAT(CAG)11 CATG-3']. Plasmids were transformed into DH5 by using the Hanahan procedure (8) or by
electroporation at 2.5 mV with a Bio-Rad E. coli pulser.
Plasmids were recovered from DH5 by using a QIAspin miniprep kit
(Qiagen) according to the manufacturer's protocol. Plasmids were
sequenced with Sequenase 2.0 by using the U.S. Biochemicals sequencing
kit and protocol to confirm the accuracy of the cloned sequence prior
to integration into yeast.
Fluctuation analysis.
Fluctuation analysis was performed as
previously described (16). The rates of TNR instability were
determined by the method of the median (14). Briefly, single
yeast colonies harboring interrupted repeats were resuspended in water
and appropriate dilutions were plated onto nonselective media (YPD).
After 24 to 36 h of growth at 30°C, 7 to 10 colonies were
resuspended in water, and an appropriate dilution was plated on YPD for
total cell counts, while the remaining suspension was plated on
selective complete medium lacking histidine but containing 1 mg of
5-fluoro-orotic acid (5FOA) per ml. To ensure reproducibility a minimum
of three repetitions of the fluctuation assay were performed per
strain, and at least three independently isolated clones were tested.
Molecular analysis of independent expansion events.
The
colonies grown on the selective media were subjected to colony PCR by
using published procedures (16). Briefly, template DNA was
released from single colonies by heating in a solution containing
dithiothreitol and Triton X-100. PCR, usually in the presence of 0.25 µCi of [-32P]dCTP, was performed with primers that
flank the triplet repeat tract. The products of the PCRs were analyzed
on a denaturing 6% polyacrylamide gel, and the product sizes (± one
to two repeats) were determined by comparison of the reaction products
with a M13 DNA sequence ladder.
Two safeguards were included to minimize microheterogeneity of the
starting tract size. First, prior to fluctuation analysis, a portion of
each colony was examined by PCR to ensure that the starting tract
contained 25 repeats. Second, after the fluctuation test, individual
colonies from the YPD plate were tested by PCR for high-resolution
analysis of the tract size. All 88 colonies tested gave PCR sizes
corresponding to 25 ± 2 repeats. Therefore, the total tract size
of 25 repeats in unselected cells was maintained throughout the experiment.
For determination of the retention and position of interruptions in the
expanded alleles, PCR products were purified by using
a QIAquick PCR
purification kit (Qiagen) according to the manufacturer's
protocol.
Purified PCR products were subjected to restriction
analysis with
SfaNI (New England Biolabs). A typical reaction
used 10,000 to 30,000 cpm of PCR product and 1.25 U of enzyme
in a total volume of
9 µl. Digestion products were displayed on
a 6% sequencing gel. In
some cases, PCR products were sequenced
to determine if either
interruption was lost during an expansion
event. PCR products for
sequencing were purified by electrophoresis
on a nondenaturing 7.5%
polyacrylamide gel buffered with 45 mM
Tris, 45 mM boric acid, and 1 mM
EDTA. Products were visualized
by ethidium bromide staining. Products
were then excised from
the gel and placed in 0.3 ml of 10 mM Tris-Cl
(pH 7.6)-1 mM EDTA.
After maceration, the gel fragments were soaked
overnight at room
temperature. Eluted PCR products were lyophilized to
100 µl and
further purified via a QIAquick PCR purification kit
(Qiagen)
according to the manufacturer's protocol. The PCR products
were
sequenced using an ABI automated sequencer following the
manufacturer's
protocol for cycle sequencing to incorporate a
fluorescently labeled
nucleotide.
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RESULTS |
Model under investigation.
We tested predictions of the model
that interruptions inhibit expansions by reducing hairpin stability
(5, 19, 21). If this is so, placement of interruptions at
different positions within the TNR tract, relative to the direction of
replication, may lead to different outcomes (Fig.
1). Interruptions near the 5' end of the
TNR will likely be synthesized prior to hairpin formation (Fig. 1A).
Interrupting bases in the newly synthesized strand might help prevent
expansions in two ways, as shown in the left side of Fig. 1A. The
interruptions might provide a reference point for proper reassociation
of the separated strands. Alternatively, folding of the daughter strand
might incorporate the interruptions into the hairpin stem, thus
weakening it. Both factors would disfavor expansions, as indicated by
the X in the left panel of Fig. 1A and as suggested previously (5,
19, 21, 26). The right panel depicts hairpin formation without
including the interruptions. Under these circumstances, expansions
would proceed unhindered. This model predicts that 5' interruptions
should have a large stabilizing effect because many expansions would be
precluded. Duplication of the interruption should be rare since only
the left panel generates duplications. Events occurring via the scheme presented in the right panel would lead to polar expansions, with new
repeats added after the interruptions. The size of these expansions would most frequently be limited by the size of the perfect tract.
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FIG. 1.
Model of interrupt-mediated stabilization. In
this schematic the open boxes represent nonrepetitive flanking
sequence, the lines denote the TNR, the filled circles symbolize the
interruptions, arrowheads mark the 3' end of the Okazaki fragment, and
carats represent mismatches. The illustration uses two interruptions,
since this is a frequently observed allele in the relevant human
disease genes. (A) Two possible outcomes are shown for the 5'
interruption. The left panel represents hairpin folding that
incorporates the newly synthesized interruptions into the stem of
the hairpin. Expansions in the left panel are disfavored, as denoted by
the "X" and as described in the text. The right panel shows a
possible mechanism for expansion in which the hairpin does not include
the interruptions. Replicational extension leads to the precursor for
an expanded allele. Note that the expansion in the right panel is
predicted to occur downstream (3') of the interruption. (B) Two
outcomes are displayed for the 3' interruption. The left panel would be
expected to produce expansions more often than the right panel (denoted
by "X"). Expansions arising from the left panel should occur
upstream (5') of the interruption. (C) Two pathways leading to
expansion of the central interruption. In the left panel, expansions
are predicted to be  11 repeats and to occur upstream of the
interruption. In the right panel, interruptions are incorporated in or
near the loop of the hairpin and thus have a limited negative impact on
hairpin formation. Expansions arising from the right panel are expected
to duplicate the interruption. Although not shown, disfavored
structures like those in panels A and B are also possible when the
interruptions are incorporated into the stem of the hairpin.
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Figure
1B indicates that 3' interruptions should lead to a lesser
degree of stabilization. In the left panel, hairpin formation
frequently occurs prior to synthesis of the interruptions. Since
the
Okazaki fragment contains a perfect repeat, hairpin formation
can
proceed unhindered. The right panel shows the less-frequent
case where
synthesis includes the interruptions and thus hairpin
formation would
be disfavored. Based on the model, expansions
from 3' interruptions
should be polar, with new repeats inserted
before the interruptions,
and duplications should be
rare.
Centrally located interruptions (Fig.
1C) provide two scenarios where
expansions might proceed unhindered. The left panel
shows small
hairpins forming prior to synthesis of the interruptions.
These events
are relatively uncommon, based on the fact that small
expansions from
perfect repeats make up only a minor portion of
events in our system
(
16). Expansions that arise from this mechanism
should be
limited to the number of repeats preceding the interruptions
and will
not show duplication of the interruption. As shown, the
polarity is 5'
to the interruption. Although expansions with 3'
polarity are also
possible, no events with 3' polarity were observed
experimentally. The
right panel of Fig.
1C indicates hairpin folding
with the interruptions
in or near the loop. This folding is expected
to have less of an effect
on hairpin stability than if the interruptions
are in the stem. If so,
expansions might proceed more readily
and should yield relatively large
expansions due to the requirement
for added base pairing in the stem to
overcome the slightly unfavorable
effect of the interruptions in the
loop. Duplication of the interruption
will result by the scheme
presented in the right panel of Fig.
1C. Our experimental results are
consistent with expansions of
this type. Disfavored events, where
interruptions are included
in the stem of the hairpin, have been
omitted from Fig.
1C for
reasons of clarity. These disfavored events
are predicted to account
for a relatively large portion of possible
hairpins. Thus, expansions
arising from central interruptions should
show an intermediate
level of stabilization, less than for 5' alleles
but greater than
for 3'
interruptions.
All events in Fig.
1 are drawn as 3' slippage events. However, Gordenin
et al. (
6) suggested that expansions can also occur
by
polymerase-mediated displacement of the 5' end of an existing
Okazaki
fragment, followed by hairpin folding and ligation to
the daughter
strand. Our experiments with interrupted TNR tracts
were not designed
to distinguish between hairpins arising from
3' slippage versus 5'
flaps, since the events in Fig.
1 can be
drawn with 5' flaps and yield
virtually identical
predictions.
Choice of interrupted TNRs.
To address models for TNR
stabilization by interruptions, we examined interrupted repeats in
yeast, where rare events can be easily detected and characterized. We
generated test sequences similar to interrupted alleles of
SCA1, many of which contain one to three CAT interruptions
of CAG repeats, resulting in total tract lengths equal to 23 to 36 repeats (2). The complementary strand therefore harbors ATG
interruptions in a CTG tract. We have shown previously (16)
that perfect (CTG)25 tracts are unstable in yeast. These
tracts expand frequently (~105 per cell generation)
when present on the lagging daughter strand during DNA replication.
Therefore, if ATG interruptions stabilize CTG tracts in yeasts as in
humans, the rate of expansion should be reduced relative to an
uninterrupted control. In this work, TNR sequences were constructed
that contained two adjacently placed interruptions to maximize the
stabilizing effect (Fig. 2A). Because the
interrupted alleles were integrated at the LYS2 locus where the direction of DNA replication is known (4), the
assignment of 5' and 3' interruptions is accurately reflected in Fig.
2A.
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FIG. 2.
Selective identification of expanded TNR. (A)
Sequences represent the TNR sequences used for this study. Nomenclature
is that of the lagging daughter strand. (B) Genetic assay to select for
TNR expansions in yeast. The region controlling expression of the
reporter gene URA3 is shown, including the TATA box, the TNR
region, an out-of-frame initiation codon, the preferred transcription
initiation site (I), and the start of the URA3 gene. The
upper diagram demonstrates the starting construct. The brackets
represent a window of potential transcription initiation sites located
55 to 125 bp from the TATA box. With a 25-TNR tract, the transcription
window includes the preferred site I, thus leading to expression of
URA3 and making the yeast 5FOA sensitive. The lower diagram
demonstrates what happens when the TNR tract expands to  30 repeats.
The bracketed window does not include site I. Transcription initiating
5' of the preferred initiation site will include the out-of-frame ATG,
resulting in translational incompetence and therefore resistance to
5FOA.
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Genetic assay.
Stabilizing effects of interruptions were
assayed by using a selective, sensitive, and quantitative genetic assay
in S. cerevisiae (16). This assay (Fig. 2B)
allows the identification of expanded TNR alleles based on
phenotypic changes. Briefly, a starting tract of 25 repeats,
either uninterrupted or interrupted, allows expression of the
URA3 reporter gene with concomitant sensitivity of the cells
to the cytotoxic effects of 5-fluoro-orotic acid (5FOA). Expansions of
the tract to lengths of 30 repeats inactivate the URA3
reporter, and the cells are accordingly resistant to 5FOA. The rate of
expansion is therefore proportional to the number of 5FOA-resistant
colonies. This assay was specifically designed to reveal expansions of
5 repeats because this size class is among the most frequent in human
TNR diseases (1, 7, 18). The 5FOA assay avoids interference
by small expansions of one to four repeats or contractions. The yeast
assay also allows use of single-colony PCR to characterize the expanded
alleles (16).
Early replicated interruptions provide the greatest TNR
stabilization.
Interrupted TNRs were stabilized relative to an
uninterrupted control, as judged by lower expansion rates (Table
1). The perfect (CTG)25 tract
yielded a rate of 1.0 × 105 per cell generation, a
result consistent with our previous work (16). In contrast,
there was a stabilization of 90-fold when the interruption was placed
5' in the TNR tract. Stabilization was also observed for the 3' allele,
but the extent was much smaller, only 2.4-fold relative to the control.
When the interruption was placed in the center of the tract, the
expansion rate was reduced 16-fold compared to the uninterrupted tract.
In addition to these stabilizing effects with the reporter integrated
at LYS2, similar results were observed for integration at
URA3. The direction of replication through the repeat tract
is the same for integration at both loci (4, 16). Compared
to the uninterrupted repeat, the rate of 5FOA resistance was reduced
>20-fold by the 5' interruption and 2.9-fold by the 3' interruption,
indicating that the stabilizing influence is general rather than
LYS2 specific. We conclude that interruptions reduce the
rate of TNR expansions in yeast as they do in humans. Clearly, the
extent of stabilization depends on the placement of the interruption
with respect to the direction of DNA replication. The rate results
shown in Table 1 are in agreement with predictions from the model in
Fig. 1.
The interruptions are always retained in the expanded alleles.
The ATG interruptions within the CTG tract provide a recognition site
for the restriction enzyme SfaNI. If expanded alleles retain
the interruptions, then PCR products from these tracts should be
sensitive to the enzyme. As described in detail in the next section, we
tested a total of 60 genetically independent expansions by this method
(17 from the 5' interruption, 22 from the 3' interruption, and 21 from
the central interruption). Cleavage was observed in every case. In
contrast, a control strain with a perfect CTG repeat did not give a
cleavable PCR product. Therefore, at least one interruption was
maintained in 60 of 60 expansions from the interrupted tracts. Since
SfaNI cleavage requires that only one of the two ATGs be
retained, it was possible that the expansions had lost one interruption
either prior to or during expansion. To address this question, we
sequenced five expansions (three from the 5' interruption and two from
the 3' interruption). Sequencing determined that all five alleles
retained both ATGs.
Polarity of expansions.
Mapping of the SfaNI site
in the expanded alleles provided a means for assessing whether
expansions from interrupted tracts are polar. In other words, are the
extra triplet repeats generated preferentially on one side of the
interruption? The model in Fig. 1 predicts polarity in certain cases.
For the 5' interruptions, expansions should occur primarily downstream
of the interruption. The situation is reversed for the 3' alleles,
where expansions are expected upstream of the substitution. For the
centrally located interruptions, some events will show polarity on the
5' side (left panel of Fig. 1C). Expansions resulting from the scheme
in the right panel of Fig. 1C will not yield polar products because the expansion will occur between the original interruption and a new, duplicated copy of the interruption. If events of the latter class exist, the SfaNI site will be duplicated and therefore an
extra fragment should be observed after digestion.
By comparing the sizes of PCR products that are uncut with those
cleaved with
SfaNI, we can deduce the location of extra
triplet
repeats in the expanded alleles. The starting tracts are shown
in Fig.
3A, including the positions of
the interrupting base pairs.
Examples of this analysis are shown in
Fig.
3B. The control sample
in lanes 1 and 2 was amplified from a
strain with a perfect tract
of 25 repeats. Treatment of the sample with
SfaNI did not cleave
the DNA, as expected (compare lane 2 to
lane 1). Lanes 3 and 4
were uncut samples from the 5' interrupt; lane 3 was an unexpanded
control, and lane 4 was one of the expanded alleles.
When these
samples were treated with
SfaNI (lanes 5 and 6),
cleavage occurred.
The unexpanded sample in lane 5 gave the expected
band sizes,
corresponding to fragments A and B (Fig.
3A). The expanded
sample
in lane 6 showed that fragment A was unaltered but that fragment
B was increased in size to the position marked with an asterisk
and
that this increase matched the overall expansion size. Therefore,
this
sample showed a polar expansion downstream of the interruption.
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FIG. 3.
Example of SfaNI digests to
identify interruptions and to determine polarity of expansions. (A)
Schematic diagram of the PCR products of the unexpanded TNRs
tested. The thin line represents the TNR, the open boxes represent
the nonrepetitive flanking sequence, filled boxes show the location of
the PCR primers, and the filled circles represent the location of the
interruptions within the TNR tract. The expected fragments after
digestion of these PCR products with SfaNI are shown
(labeled A to F). The cut site for SfaNI is displaced
by five nucleotides from the recognition sequence, and restriction
fragments A to F are adjusted in size accordingly. Due to the
four-nucleotide overhang generated by SfaNI and the
fact that the PCR fragments are uniformly labeled in the presence of
[-32P]dCTP, cleaved samples should show two bands
differing in size by four bases. The expected sizes (in nucleotides)
are: fragment A, 90 and 94; fragment B, 101 and 97; fragment C,
123 and 127; fragment D, 68 and 64; fragment E, 105 and 109; and
fragment F, 86 and 82. (B) Autoradiograph of representative digests of
each of the TNRs tested. Markers were determined from a M13 sequence
ladder, and the arrow indicates the size of the uncleaved
starting tract. The table above the autoradiograph identifies which
lanes have the starting or expanded products and which of these
products were subjected to SfaNI digestion. The designation
"P" for lanes 1 and 2 indicates a perfect repeat. Labeled fragments
A to F refer to the expected fragments listed in panel A. The asterisks
in lanes 6 and 10 designate the expanded alleles of fragments B and C,
respectively. Fragment G is the result of a duplicated
interruption. The brackets indicate the products of both strands
of the digestion products, separated by four nucleotides as explained
above. Shadow bands are due to polymerase "chatter" which is
commonly seen during PCR of TNRs.
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A parallel analysis of the 3' interrupted allele also yielded polar
expansions, but in this case the addition was before the
interruption.
Lanes 7 and 8 show the uncleaved PCR fragment of
a control, unexpanded
colony (lane 7) and an expansion (lane 8).
Treatment with
SfaNI yielded the expected fragments labeled C
and D (lane
9). In the expanded sample of lane 10, the D fragment
size was
unchanged, whereas fragment C was increased to the position
marked by
the asterisk and this increase accounted for the overall
expansion
size. Comparison with the schematic diagram in Fig.
3A shows that polar
expansions located 5' to the interruption
would lead to increased size
of fragment C. A different pattern
was frequently observed when the
interruption was centrally located.
Uncleaved samples (lanes 11 and 12)
again demonstrated the expansion
for the 5FOA-resistant colony.
Cleavage of both samples yielded
the same size fragments E and F (lanes
13 and 14), indicating
that expansion did not affect these regions of
DNA. Instead, a
new fragment labeled G was observed (lane 14), a
finding consistent
with duplication of the interruption and therefore
the creation
of an extra
SfaNI site. In the example shown in
Fig.
3B, the duplication
created a fragment of 18 repeats, one presumed
to consist of 16
new CTG repeats and 2 extra ATG
triplets.
Since the interruption was retained in all 60 independent expansions
that were analyzed, polarity could be determined. As
shown in Fig.
4A, expansions of the 5' interrupted
tract were
exclusively polar, with extra DNA added after the
interruptions.
Similarly, expansions of the 3' interrupted tract (Fig.
4B) were
also polar but in this case addition was exclusively before
the
interruption. In all cases examined (39 of 39 events) for the
5'
and 3' alleles, the repeats were added to the larger perfect
repeat
tract as predicted by the model in Fig.
1. For the central
interruption, two short expansions showed a 5' addition (Fig.
4C). One
might expect an equivalent distribution of 5' and 3'
additions to the
centrally interrupted tract due to the nearly
identical perfect repeat
tract lengths on either side. However,
no 3' addition events were
detected. This may be due to the few
expansions of this size class that
were observed. As seen in Fig.
4C, the great majority (19 of 21) of
larger expansion events duplicated
the interruption. Since duplications
were defined by the generation
of a new
SfaNI fragment,
there must be at least one ATG repeat
at each end of the expansion. We
presume that both ATG repeats
were duplicated, although this point was
not tested. It is also
noteworthy that the size of the duplication
frequently exceeded
the largest perfect repeat stretch, 12 triplets,
present in the
starting tract. Therefore, any single expansion event
must have
bridged the site of the interruption.
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FIG. 4.
Polarity of expansions for the interrupted
TNRs. The open circles represent a CTG repeat, and the filled circles
represent an ATG interruption. In panels A through C the starting
allele is designated as Start. On the side of each represented TNR is
the number of triplet repeats added (+13, etc.) and the number of times
the expanded TNR was observed. (A) Expanded products of the 5'
interrupted TNR. (B) Expansions arising from the 3' interrupted TNR.
(C) Expansions of the centrally interrupted TNR. In panel C, expansions
that led to duplication of the interruption are labeled as "dup."
The size values indicate the total number of repeats added, including
the duplication. For example, "+14 dup." means that 12 extra CTGs
and 2 extra ATGs were present. The expansion polarity of the duplicated
alleles could not be determined, and those events are diagrammed
symmetrically below the starting allele.
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Effects of the interruption location on the expansion product
size.
The predictions from Fig. 1 suggest that expansions from
tracts containing either 5' or 3' interruptions will be limited to increases of 17 repeats, since this limit is set by the longest uninterrupted repeat stretch for these alleles. For interruptions in
the center of the TNR tract, a mixture of sizes was predicted. In
addition to the events illustrated in Fig. 4B, we examined the sizes of
more expansions arising from each type of tract to generate a
mutational spectrum. Expansions from the perfect TNR tract provide a
useful comparison. They range in size from 10 to 22 repeats with a
median of 15 (Fig. 5A), a result
consistent with a previous report (16). The expansion
products seen in the 5' interrupted TNR (Fig. 5B) were of similar size
(13 to 23, with a median of 15). Of the 19 independent events examined
for the 5' interrupted tract, all but three fell within the predicted size limit of the model. Among the expansions from the 3' interrupted tract (Fig. 5C), all 36 were of the predicted size class. However, all
but one of the expanded alleles stemming from the 3' interrupted TNR
fell into an apparently smaller grouping (range, 5 to 11; median, 8)
than for the perfect tract or for the 5' interruption. The products of
expansion seen for the 3' interruption were significantly different
than the products recovered from expansion of the perfect repeat tract
or the 5' interrupted tract, as judged by the Student's t
test (P < 0.001 in each case). The major consequence
of the 3' interruption was a change in the spectrum of mutations and not a reduction in the rate of expansions.
View larger version (14K):
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|
FIG. 5.
Distribution of sizes of the expansion events. On the
x axis is the number of repeats added with respect to the
starting tract length (e.g., +11 repeats indicates a final length of 36 TNR). On the y axis is the observed number of expansion
events of that size. (A) Twenty genetically independent expansions of
the uninterrupted sequence (CTG)25. (B) Nineteen expansions
of the 5' interruption. (C) Thirty-six expansions of the 3'
interruption. (D) Thirty-three expansions of the centrally located
interruption.
|
|
Expansions from the centrally interrupted TNR tract (Fig.
5D) showed a
wide distribution ranging in size from 7 to 21 repeats.
However, this
distribution appeared bimodal, with a few small
expansions of 7 to 9 repeats and the rest large expansions of
14 to 21 repeats. The smaller
class of expansions appears to overlap
the small size class observed
with 3' interrupted alleles (compare
panels C and D of Fig.
5). From
the model (left panel of Fig.
1C), we expected that some events might
be limited to expansions
of
11 repeats. We observed about 10% (3 of
33) fell into this
grouping. In contrast, 90% of the expanded alleles
were of a larger
class that more closely resembled alleles arising from
the perfect
repeat or from the 5' interruption (compare panel D with
panels
A and B of Fig.
5). We know from Fig.
4C that most of the larger
class of expansions is due to events like those shown in the right
panel of Fig.
1C, in which the expansion duplicated the
interruption.
| |
DISCUSSION |
The results of this study indicate that interrupted trinucleotide
repeats are stabilized in yeast, as has been suspected for humans. The
yeast experiments support a model where interruptions contribute in
cis to reduce the likelihood of secondary structure during
TNR replication. By varying the position of the interruption, we
provided supporting evidence that verifies several key predictions. First, the degree of stabilization depends on the location of the
interruption. Replication early in the tract provides the greatest
stabilization, late replicating interruptions are least stabilizing,
and central interruptions give an intermediate amount of stabilization.
Second, the expansion sizes for the asymmetrically placed interruptions
were restricted to the larger available stretch of perfect repeats,
closely mirroring the predictions from the model. Third, expansions
from the asymmetric alleles were polar but did not lead to duplication
of the interruption. Fourth, 90% of the expansions from a centrally
placed interruption appear to span the interruption, leading to its
duplication. We believe that the duplications provide a particularly
compelling point in favor of the hairpin destabilization model.
Although an anchoring effect by the interruptions may contribute to
stability by reducing replicational slippage (19, 26),
anchoring does not easily explain the duplications. Taken together,
these results indicate that interruptions act in cis to help
stabilize TNR tracts.
An alternative model for interruption-mediated stabilization is that
the interruptions break up a long, unstable TNR into two smaller,
genetically stable subthreshold lengths. For fragile X CGG repeats, one
model is that subthreshold lengths of perfect repeats might lengthen by
the accumulation of short slippage mutations (3, 9, 22, 25).
Given the caveat that thresholds have not yet been demonstrated in
yeast, our evidence suggests that interruptions do not act merely to
generate a subthreshold length repeat. Comparison of the 5' and 3'
interrupted tracts shows that both have 17 perfect contiguous repeats
but that their expansion rates vary by 40-fold. Furthermore, the
central interruption contains the shortest perfect repeat tract (12 repeats), yet it expands at a fivefold-higher rate than the 5'
interruption which has a longer perfect repeat tract. A second
noteworthy point is that we found no evidence for gradual accumulation
of short slippage events. PCR analysis of expanded and unexpanded
siblings showed no tracts of intermediate lengths. Thus, in our yeast
system, the stabilizing influence of interruptions on CTG tracts does not conform to the subthreshold model.
The work of Pearson et al. (19) examined SCA1 and
FMR1 perfect and interrupted alleles from the human
population. Their study demonstrated that interruptions decreased the
total amount of S-DNA compared to perfect repeats. Their work also
showed that interrupted tracts show less heterogeneity in the number of
S-DNA isomers formed, suggesting that the interrupting base pairs limit S-DNA formation to regions of perfect repeats. Our data demonstrate that a smaller range of expansions is seen for asymmetrically located
interruptions compared to a perfect repeat of the same length (Fig. 5A
to C). Our model (Fig. 1) suggests that the interruptions reduce the
likelihood of hairpin formation if the stem contains mispairs due to
the interrupting bases. Another possible interpretation is that
interruptions delimit boundaries for hairpins, like S-DNA. However,
when we placed the interruption in the center of the TNR we observed
frequent duplications, a result consistent with incorporation of the
interruption in or near the stem of the hairpin. The latter result more
closely supports the hairpin destabilization model compared to the
boundary hypothesis.
One unexpected result from our work was that a few expansions of the 5'
interruptions were slightly larger (+18 to +23 repeats; Fig. 5) than
that predicted by the hairpin destabilization model (+17 repeat
maximum). These exceptional mutations accounted for 21% (4 of 19) of
the expansions examined for the 5' interrupted tract. If they occurred
by a complex event, such as multiple slippage events in a single round
of replication, the larger expansion size could be explained. One would
expect multiple slippages to occur with low frequencies. Consistent
with this prediction, we note that these alleles were only observed for
the repeat tract with the lowest overall expansion rate and even then
they comprised only a fraction of the total expansions. A second
unanticipated result was that expansions from the 3' interrupted allele
tend to be shorter than for a perfect repeat or for the 5' interruption (Fig. 5). Either small hairpins are somehow stabilized for the 3'
interrupted tract or large hairpins are selected against, even if the
interrupting base pairs have not been replicated. Since the overall
rate of expansion for the 3' interruption was reduced only 2.4-fold
relative to the perfect tract, it seems unlikely that there could be
much selection against the large hairpins or else the rate would be
more severely reduced. Thus, small expansions from the 3' interrupted
allele are not readily predicted either by the hairpin destabilization
model or by the boundary model. The subthreshold model suggests that
expansions can accumulate from several short slippage events. We note,
however, that the accumulation hypothesis is an unlikely explanation
for our result because examination of the unexpanded sibling colonies
showed no evidence for lengthening of the starting tract. The
observation of short expansions associated with 3' interruptions will
require additional experimentation for a satisfactory explanation.
In another yeast study, Maurer et al. (15) used tracts of 90 to 97 CAG repeats containing a single CAT interruption to investigate the polarity of repeat mutations. They observed only contractions in
unselected populations of wild-type cells. Since no expansions were
observed in their wild-type background, it is difficult to compare
their results with our work.
The model presented in Fig. 1 depicts hairpin formation by 3' slippage
of Okazaki fragments. The 5' flap model (6) can explain many
of our results equally well. In the flap model, a DNA polymerase
sometimes displaces the 5' end of an existing Okazaki fragment within
the TNR. Since the flap contains TNR sequences, it can fold into a
hairpin. One of our results suggests that expansions may result more
often from 3' slippage than 5' flaps. The observation is that
interruptions that are replicated early are more stabilizing than
late-replicated alleles. By the 3' slippage model, slippage is more
likely (based on probability) to occur after synthesis of the
early-replicated interruptions, leading to hairpins that contain the
substitutions. In contrast, slippage first is more likely for the
late-replicated interruptions. One would then expect the 5' interrupted
TNR to provide greater stability than the 3' interrupted TNR. Indeed,
this was the observation. If, on the other hand, one envisions the flap
model, it would seem more probable that the 5' end of the displaced
fragment would lie downstream of the 5' interruption. Therefore, the
interruption would not reside within the flap and would not affect
hairpin formation. In contrast, late-replicated interruptions would
more often be included in the flap and have a greater chance of
inhibiting hairpin formation. By this view, the 3' interruption would
stabilize more than the 5' interruption but the experimental
observation is the opposite. From this analysis, TNR hairpin formation
would seem more likely from 3' slippage events than from 5' flaps.
However, this point is based on a number of assumptions, and therefore it provides only an indirect test of the 3' slippage versus 5' flap models.
Based on findings from human TNR diseases, we were surprised to find
that the interruption was retained in all 60 independent events that
were analyzed. Sequence analysis of five samples showed that both
interrupting ATGs were still present. Thus, in our yeast system loss of
the interruption is not required for expansions. Analysis of human
pedigrees for disease loci such as SCA1 and FMR1
shows a majority of stable repeats have one to three interruptions, while the disease alleles have zero to one interruption (2, 3, 9,
13, 25). This correlative information has led to the belief that
loss of an interruption precedes expansion in the human population,
although it has not been possible to show this unambiguously. Perhaps
there are multiple mechanisms by which interrupted alleles can expand
and our yeast system exemplifies one of those mechanisms. Although the
human diseases reported to date are suggestive of loss of interruptions
upon expansion, it is possible that new TNR disease genes may exhibit
genetic characteristics more like the yeast system.
The results of this study have been interpreted as the interruptions
acting in cis to inhibit expansions. We note that
trans-acting factors may also contribute to the stability
provided by interruptions in TNRs, as suggested by others (12,
20). Candidate trans-acting factors are currently
being investigated. It is also possible that the direction of
transcription through the repeat vis-á-vis the direction of
replication could affect stabilization. Evaluation of this possibility
will require further experimentation.
| |
ACKNOWLEDGMENTS |
This work was supported by funds from the Eppley Institute (to
R.S.L.), by National Cancer Institute (NCI) training grant T32 CA09476
(to M.L.R.), and by NCI Cancer Center support grant P30 CA36727 (to the
Eppley Institute).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Eppley Institute
for Research in Cancer and Allied Diseases, University of Nebraska Medical Center, Box 986805, Omaha, NE 68198-6805. Phone: (402) 559-4619. Fax: (402) 559-4651. E-mail: rlahue{at}unmc.edu.
| |
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Top
Abstract
Introduction
