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Molecular and Cellular Biology, February 2000, p. 1361-1369, Vol. 20, No. 4
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Yeast Meiosis-Specific Protein Hop1 Binds to G4 DNA
and Promotes Its Formation
K.
Muniyappa,1,2
S.
Anuradha,1 and
Breck
Byers2,*
Department of Biochemistry, Indian Institute
of Science, Bangalore 560012, India,1 and
Department of Genetics, University of Washington, Seattle,
Washington 981952
Received 28 July 1999/Returned for modification 22 September
1999/Accepted 19 November 1999
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ABSTRACT |
DNA molecules containing stretches of contiguous guanine residues
can assume a stable configuration in which planar quartets of guanine
residues joined by Hoogsteen pairing appear in a stacked array. This
conformation, called G4 DNA, has been implicated in several aspects of
chromosome behavior including immunoglobulin gene rearrangements,
promoter activation, and telomere maintenance. Moreover, the ability of
the yeast SEP1 gene product to cleave DNA in a
G4-DNA-dependent fashion, as well as that of the SGS1 gene
product to unwind G4 DNA, has suggested a crucial role for this
structure in meiotic synapsis and recombination. Here, we demonstrate
that the HOP1 gene product, which plays a crucial role in
the formation of synaptonemal complex in Saccharomyces cerevisiae, binds robustly to G4 DNA. The apparent dissociation constant for interaction with G4 DNA is 2 × 10
10,
indicative of binding that is about 1,000-fold stronger than to normal
duplex DNA. Oligonucleotides of appropriate sequence bound Hop1 protein
maximally if the DNA was first subjected to conditions favoring the
formation of G4 DNA. Furthermore, incubation of unfolded
oligonucleotides with Hop1 led to their transformation into G4 DNA.
Methylation interference experiments confirmed that modifications
blocking G4 DNA formation inhibit Hop1 binding. In contrast, neither
bacterial RecA proteins that preferentially interact with GT-rich DNA
nor histone H1 bound strongly to G4 DNA or induced its formation. These
findings implicate specific interactions of Hop1 protein with G4 DNA in
the pathway to chromosomal synapsis and recombination in meiosis.
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INTRODUCTION |
In meiosis, two successive rounds of
nuclear division follow a single round of chromosomal DNA replication,
reducing the diploid genome to haploidy in preparation for conjugation
of the gametes. Faithful recombination between the homologs and their
appropriate segregation in the reductional division typically depends
on their precise synapsis in prophase of meiosis I. Synapsis typically involves the assembly of the synaptonemal complex (SC), a highly ordered proteinaceous structure consisting of a central region flanked
by two lateral elements. Each lateral element serves as the common core
for the two sister chromatids derived from each homolog (reviewed in
references 18, 32, and 48). An
earlier viewpoint held that SC assembly preceded all stages of
recombination, juxtaposing the homologs so that crossing over would
later occur only between well-aligned homologous sequences. However,
temporal and genetic analysis of sporulation in the budding yeast
Saccharomyces cerevisiae has revealed that the initial
phases of recombination take place much earlier than synapsis and
probably contribute to the proper association of the homologs (reviewed
in references 18, 19, and 32).
Specifically, double-strand breaks (DSBs) are created by the action of
the SPO11 gene product in conjunction with the products of
several other early meiotic genes well before the assembly of SC
(14, 15). Resection of the DSBs exposes a free 3'
single-stranded end that, in association with RecA-like proteins, may
participate in a search for the complementary sequence in the homolog
(reviewed in reference 19). Concerted strand invasion by both of the free ends created by the DSB leads to the
formation of a joint molecule that stably interconnects the homologs
(reviewed in reference 18). This configuration
appears to persist throughout meiotic prophase and then undergo
resolution at the end of the pachytene phase, when SC disassembly
occurs and recombinant DNA strands can first be detected (5, 35, 36).
Genetic analysis of meiotic recombination in S. cerevisiae
has provided considerable insight into the functional relationships between these processes (reviewed in reference 21).
Numerous mutations that abolish DSB formation (such as rad50
and spo11) or later steps of DSB processing (including
dmc1 and rad51) generally prevent SC formation
(reviewed in references 18 and
32). On the other hand, null mutations in other
genes prevent normal synapsis but do not completely abolish
recombination. One such gene is ZIP1, which encodes a major
structural element of the central core of the SC (43, 44).
zip1 mutants are reduced for crossing over about twofold and
notably lack chiasma interference, thus implicating the SC in
controlling the distribution of crossovers along the chromosomes
(42). Other mutations that block synapsis are found in
HOP1, RED1, and MEK1, all three of
which are required in some manner for the formation and synapsis of the
lateral elements (13, 28-30, 40). Hop1 is a DNA-binding
protein (17) that appears to act conjointly with Red1 to
form a highly condensed core structure that facilitates joining of
sister chromatids (40), while Mek1 is a protein kinase
controlling the behavior of these other proteins (2, 11,
30). The inability of hop1 or red1 mutations to protect against the meiotic lethality of rad52,
which renders DSBs irreparable, indicates that neither HOP1
nor RED1 is essential for DSB formation (12, 24, 26,
29). These findings might be interpreted as evidence that the
Hop1-Red1 assemblage acts only in the later stages of recombination,
after the DSB has been created. However, the appearance of DSBs is
reduced and delayed in hop1 meiosis, suggesting a role for
Hop1 in DSB formation (18). These seemingly contradictory
findings concerning the role of Hop1 in meiotic synapsis and
recombination motivated us to explore the properties of the gene
product in vitro.
Biochemical characterization of the HOP1 gene product had
previously shown it to be an oligomeric DNA-binding protein with a
greater affinity for negatively supercoiled DNA than for nicked circular duplex DNA (17). Potentially, such binding to
underwound duplex DNA within the chromosomes could anchor one homolog
to the other while the DSB repair pathway acted in parallel to generate the more specific homologous interactions required for recombination. On the other hand, Hop1 has been shown to confer protection against the
exonucleolytic degradation of linear duplex DNA that occurs in extracts
of meiotic nuclei, suggesting a role for Hop1 in modulating the
processing of DSBs (17). In either case, it may benefit our
understanding of synapsis to learn whether there is any sequence specificity in the interaction of Hop1 protein with substrate DNA.
Although assays for its binding to plasmid DNA and oligonucleotides initially failed to reveal sequence specificity, it was shown that Hop1
binding to double-stranded M13 DNA is competitively inhibited by G-rich
oligonucleotides (17). Realization that these G-rich
sequences are capable of forming G-quartet structures (G4 DNA) led us
to explore the possibility that G4 DNA may be significant to Hop1
binding in vitro and perhaps crucial to its role in meiosis.
The G quartet, the structural unit of G4 DNA, is a nucleic acid motif
in which four guanine bases are joined by Hoogsteen pairing in a cyclic
planar array. When each base is situated within an uninterrupted track
of G residues along its constituent DNA strand, a stack of G quartets
can be formed, and this overall assemblage (known as G4 DNA when all
four strands are in parallel orientation and as G2' DNA when two
strands are antiparallel) stably joins all four phosphodiester
backbones into a unitary structure that strongly resists dissociation
(reviewed in reference 49). In this report,
henceforth, we will refer to both types as G4 DNA. The ability of
natural sequences from immunoglobulin switch regions, gene promoters,
and telomeres to form G4 DNA under physiological conditions has
attracted considerable attention. Although it has not been proven that
G4 DNA exists within the yeast cell, its probable significance to
meiosis is evident from the finding that the product of the
SEP1/KEM1 gene, which is essential for normal progression
through meiotic prophase, displays a G4-DNA-specific nuclease activity
(16, 22, 23, 45). In addition, the identification of a
resolvase activity in humans (10) and the Sgs1 helicase in
S. cerevisiae (41), both of which are able to
unwind G4 DNA to single-stranded DNA, further attests to the probable
biological significance of G4 DNA in vivo. In the present study, we
have assessed the ability of purified Hop1 to interact with G4 DNA and
have detected avid binding. We also show here that Hop1 catalyzes the
transformation of DNA into this configuration, further implicating G4
DNA in the mechanism of meiotic synapsis and recombination.
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MATERIALS AND METHODS |
DNA and proteins.
Chemicals were of analytical grade, and
solutions were prepared using Milli Q pure water. T4 polynucleotide
kinase was obtained from New England Biolabs, Beverly, Mass., and
biochemicals were from Sigma Chemical Company, St. Louis, Mo. All
oligonucleotides used in this study were purchased from Keystone
Laboratory Inc., Menlo Park, Calif.; their sequences are listed in
Table 1. Oligonucleotides were labeled at
their 5' ends using [
-32P]ATP and T4 polynucleotide
kinase and were isolated by electrophoresis on 8 M urea-8%
polyacrylamide gels as described elsewhere (34). G4 DNA was
prepared and isolated as described elsewhere (38). Briefly,
32P-labeled substrates were incubated in a buffer
containing 20 mM Tris-HCl (pH 8), 120 mM KCl, and 1 mM EDTA at 37°C
for 16 h. Samples were electrophoresed at 4°C in 6%
nondenaturing polyacrylamide gels at 10 V/cm for 4 h. The band
corresponding to G4 DNA was excised, and DNA was eluted by crushing and
soaking the gel in TE buffer (10 mM Tris-HCl [pH 7.5], 0.1 mM EDTA)
containing 0.3 M NaCl at 40°C for 16 h. The suspension was
centrifuged, and G4 DNA in the supernatant was precipitated with
ethanol in the presence of 0.3 M ammonium acetate. The pellet was
washed with 70% ethanol and resuspended in TE buffer containing 50 mM
KCl. G4 DNA was isolated by gel filtration on Sephadex G-50. Aliquots
were stored at 
20°C in TE buffer containing 50 mM KCl. Circular
single-stranded and negatively superhelical DNA were prepared from
bacteriophage M13 (20). Linear DNA was prepared by cleaving
negatively superhelical DNA with HaeIII as specified by the
vendor. The concentration of DNA was estimated at
A260 nm and expressed as moles of nucleotide residues. RecA proteins from Escherichia coli and
Mycobacterium tuberculosis (20), Hop1 protein
from S. cerevisiae (17), and histone H1
(27) were purified, and their concentrations were determined
as described previously (17).
Electrophoretic mobility shift and competition assays.
The
standard buffer (20 µl) for the DNA-binding assay contained 10 to 20 pmol of 32P-labeled single-stranded DNA or G4 DNA in 20 mM
Tris-HCl (pH 7.5), 0.1 mM ZnCl2, and Hop1 protein at the
indicated concentrations. In experiments involving RecA proteins,
reactions were done in a buffer (20 µl) containing 30 mM Tris-HCl (pH
7.5), 1.5 MgCl2, and RecA protein at the indicated
concentrations. Unless mentioned, all the reactions were performed at
30°C for 30 min. Samples were loaded onto a 6% polyacrylamide gel
and electrophoresed at 4°C in 45 mM Tris-borate buffer (pH 8.3) at 10 V/cm for 4 h. The gel was dried at 60°C on a Whatman 3 mM filter
paper, and DNA-protein complexes were visualized by autoradiography.
To assay the effect of competitors, Hop1 protein and serial dilutions
of unlabeled competitors were premixed in the standard
assay buffer
prior to the addition of labeled DNA probe. The reaction
mixtures were
incubated at 30°C for 30 min. Samples were electrophoresed,
and the
amount of protein-DNA complexes formed in the absence
or presence of
competitors was visualized as described
above.
Assay for the formation of G4 DNA.
Reactions were carried
out in a buffer containing 20 mM Tris-HCl (pH 7.5), 0.1 mM
ZnCl2, and 5 pmol of 32P-labeled
oligonucleotide in the absence or presence of indicated concentrations
of Hop1 protein, or histone H1, for 30 min at 30°C. The reaction was
terminated by the addition of proteinase K, KCl, and sodium dodecyl
sulfate (SDS) to final concentrations of 0.2 mg/ml, 0.12 M, and 0.2%,
respectively. After incubation for 30 min, samples were loaded onto 6%
nondenaturing polyacrylamide gel and electrophoresed at 4°C in 45 mM
Tris-borate buffer (pH 8.3) at 10 V/cm for 4 h. The formation of
G4 DNA was visualized by autoradiography as described above.
DMS interference.
Methylation of single-stranded
oligonucleotides was performed by incubating 32P-labeled
DNA with 0.05% dimethyl sulfate (DMS) in TE buffer (pH 8) at 24°C
for 5 min (partial methylation) or 30 min (full methylation). The
reaction was stopped by the addition of 50 µl of solution containing
1.5 M sodium acetate (pH 6), 1 M 2-mercaptoethanol, and 200 µg of
yeast tRNA per ml. DNA was precipitated by ethanol and collected by
centrifugation at 15,000 × g for 15 min, and the
pellet was washed with 70% ethanol. The pellet was dried and resuspended in 20 µl of TE buffer containing 100 mM KCl, and the methylated DNA was used in binding experiments. In the second set of
experiments, partially methylated 32P-labeled DNA (5 pmol)
was incubated with 100 to 250 nM Hop1 protein at 30°C for 30 min.
After addition of proteinase K (0.2 mg/ml), samples were incubated at
30°C for 30 min, loaded onto a 6% nondenaturing polyacrylamide gel,
and electrophoresed as described above. The bands corresponding to G4
DNA and its single-stranded form were excised; DNAs were isolated from
the crushed gel, precipitated by ethanol, and then subjected to
cleavage by incubation with 1 M piperidine at 90°C for 15 min
(25). Samples were dried, and the pellets were resuspended
in 30 µl of water. This procedure was repeated two more times. The
pellets were dissolved in a solution containing 95% deionized
formamide, 10 mM EDTA, and 0.05% each bromophenol blue and xylene
cyanol. The products were analyzed on 20% polyacrylamide gels in the
presence of 7 M urea.
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RESULTS |
Binding of Hop1 to guanine-rich DNA is sequence specific.
To
investigate the molecular function of the HOP1 gene product,
we had previously devised methods for abundant overexpression of
HOP1 in vegetative cells and for purification of Hop1
protein to homogeneity. We found that purified Hop1 bound efficiently to duplex DNA with little, if any, apparent sequence specificity, but
this binding was competitively inhibited by oligonucleotides with
G-rich sequences (17). Recognition that the more effective competitor sequences contained multiple stretches of contiguous guanine
residues, rendering them capable of assuming the G4 DNA configuration
(49), suggested that G quartets may play an important role
in the observed DNA binding by Hop1 protein. To explore this, we tested
Hop1 binding to a series of oligonucleotides containing one or more
tracts of contiguous guanine residues (Table 1). Hop1 protein was
incubated with [-32P]ATP-labeled oligonucleotides, and
the reaction mixtures were separated by nondenaturing gel
electrophoresis and analyzed by autoradiography. In a typical
experiment (Fig. 1), Hop1 protein displayed a higher affinity for those oligonucleotides with the greater
numbers of guanine repeats. A 36-mer bearing a single stretch of four
guanine residues (1G4) formed only a barely detectable band of
protein-DNA complexes at two Hop1 concentrations tested, whereas a
similar 36-mer containing two tracts of guanine residues (2G4) formed a
faint but distinct band after incubation with Hop1 at the higher
concentration. Other oligonucleotides containing multiple stretches of
G residues formed complexes more abundantly. Oligonucleotide 6G3, which
contains six segments of guanine repeats, bound Hop1 most efficiently,
leading to the formation of two major complexes in addition to several
minor species.
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FIG. 1.
Hop1 protein binds selectively to oligonucleotides
containing contiguous G-rich residues. Reaction mixtures (20 µl)
contained 20 mM Tris-HCl (pH 7.5), 0.1 mM ZnCl2, 10 pmol of
32P-labeled oligonucleotide (Table 1), and the specified
concentration of Hop1 protein. Samples were incubated at 30°C,
separated on a 6% polyacrylamide gel, and visualized by
autoradiography.
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A simple explanation for these results is that Hop1 protein forms a
specific complex with DNA that has undergone G-quartet
formation either
by zigzag folding within a single oligonucleotide
with four or more
guanine repeats or by forming a complex of multiple
oligonucleotides,
each of which may have fewer repeats. To explore
complexes of the
latter type, we tested oligonucleotide TP, a
49-mer that was used
previously to test the G4-DNA-specific nuclease
encoded by
KEM1/SEP1 (
22,
23). Liu et al. (
23)
had shown
that TP forms G4 DNA less efficiently than 2G4. Consistent
with
this, Hop1 formed complexes with TP less abundantly than with
2G4.
No complexes were seen with TPmut (Table
1), which lacks
guanine
repeats entirely. Together, these experiments suggest
that
high-affinity binding by Hop1 protein to these oligonucleotides
does
not depend simply on the presence of G-rich sequences but
requires that
the DNA acquire the G4 configuration. This possibility
was explored
further by testing an oligonucleotide (4G3mut) that
differs from 4G3 in
the sequences intervening between the second
and third repeats, as this
pattern of residues does not permit
G4 DNA formation (
49).
Consistent with the concept that G4 DNA
formation is crucial for stable
binding, Hop1 protein clearly
bound well to the 38-mer that can form G4
DNA (4G3) but not to
the mutant derivative (4G3mut). These findings
establish that
efficient recognition of G-rich DNA by Hop1 protein
requires that
the DNA contain a sequence that is capable of forming G4
DNA
efficiently.
Hop1 protein displays greater affinity for G4 DNA.
To
establish whether Hop1 binding depends on the actual folding of the DNA
substrates into the G4 DNA configuration, we tested binding with
oligonucleotides that previously had been converted into G4 DNA. This
conversion was accomplished by incubating appropriate concentrations of
the oligonucleotides at 37°C for 16 h in a buffer containing 120 mM KCl (38). Electrophoresis under nondenaturing conditions
and visualization under UV illumination revealed partial conversion of
the oligonucleotides into forms with reduced mobility (data not shown),
as expected for the behavior of G4 DNA that has formed between pairs of
oligonucleotides (49). The band corresponding to G4 DNA was
excised from the gel and isolated by electroelution (34).
This G4 DNA and the corresponding monomeric form were assayed
separately for complex formation with increasing concentrations of Hop1
protein while keeping the DNA concentration constant. Figure
2A shows that the yields of DNA-protein
complexes increased with increasing concentrations of Hop1 protein, and there was a concomitant reduction in the amount of free G4 DNA. The
autoradiograms were scanned in a laser densitometer for
quantification (Fig. 2B). We infer that the high affinity of Hop1
protein for G-rich DNA depends on the ability of that DNA to form G
quartets. These findings, as well as the results of similar experiments (data not shown), enable us to quantify the affinity. We estimate that
the dissociation constant for binding of Hop1 protein to G4 DNA is on
the order of 2 × 1010 M, indicative that this
binding is about 1,000-fold stronger than that shown earlier for its
interaction with normal duplex DNA (17).
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FIG. 2.
Binding of Hop1 protein to G4 DNA. (A) Electrophoretic
mobility shift assays for G4 DNA-Hop1 protein complexes. Ten picomoles
of 32P-labeled G4 DNA (left half) or its single-stranded
form (49-mer TP DNA; right half) was incubated in the absence or
presence of increasing concentrations of Hop1 protein and analyzed by
polyacrylamide gel electrophoresis and autoradiography. Lane 1 and 9 represent substrate DNA lacking added Hop1 protein. TP G4 DNA (lanes 2 through 8) or its single-stranded form (lanes 10 through 16) was
incubated with 25, 50, 100, 250, 500, 750, and 1,000 nM Hop1 protein,
respectively. M, unfolded monomeric form of TP. (B) Quantitation of
Hop1 protein binding to G4 DNA and to unfolded precursor TP, as
determined by scanning the autoradiograms in panel A with a laser
densitometer.  , TP (G4) DNA-Hop1 protein complexes;  , complexes
of Hop1 protein with TP without prior folding (right half of panel A);
 , unfolded TP remaining unbound by Hop1 protein after incubation in
the presence of G4 DNA (left half of panel A).
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Specific requirements for Hop1 binding to G4 DNA.
To explore
the specificity of Hop1 interaction with G4 DNA, we assayed the binding
of 32P-labeled G4 DNA in the presence of unlabeled
competitors differing in the ability to form G quartets. As shown in
Fig. 3, Hop1 binding was not suppressed
by a 10- to 50-fold excess of either of two unlabeled competitors that
lack G4 DNA configurations
single-stranded M13 DNA and oligonucleotide
TPmut. On the other hand, addition of unlabeled G4 DNA competed
effectively, displacing the labeled oligonucleotide from its
association with Hop1. Surprisingly, inclusion of duplex M13 DNA in the
reaction mixture resulted in increased association of the labeled
oligonucleotide with Hop1. The basis for this enhancement is unknown,
but it seems plausible that the catalysis of G4 DNA formation by Hop1
protein (described below) is assisted in some manner by undefined
sequences within the duplex M13 DNA. Regardless of this apparent
enhancement, these experiments clearly demonstrate that
G4-DNA-containing oligonucleotides compete for binding to Hop1 protein.
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FIG. 3.
Competitive inhibition of Hop1 protein binding to G4
DNA. Samples contained 10 pmol of 32P-labeled TP (as G4
DNA), 0.5 µM Hop1 protein, and the indicated concentrations of
unlabeled competitor DNA substrates. The relative mass of unlabeled TP
DNA was 10, 50, or 100 pmol; that of TPmut DNA or M13 DNA in
single-stranded or linear duplex form was 50, 100, 250, or 500 pmol.
Reaction mixtures were incubated and analyzed as described for Fig. 1.
TP(G4) denotes G4 DNA prepared from 49-mer TP DNA, M is its constituent
monomer, and TPmut is the mutant analogue. M13 RF III is linear duplex
DNA generated by cleaving form I M13 DNA with HaeIII, and
M13 ssDNA is the positive strand isolated from virions.
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Other parameters controlling Hop1 binding were explored by varying the
reaction conditions. Figure
4A shows that
binding had
already occurred strongly within the briefest incubation
period
tested (2 min) and did not change appreciably with longer
incubations.
We also explored the effect of added zinc ion because (i)
the
Hop1 sequence contains an apparent zinc ion-binding motif
(
12),
(ii) zinc is detectable in the purified protein, and
(iii) addition
of zinc ion was already shown to affect DNA binding
(
17). Figure
4B shows that added Zn
2+ led to a
moderate increase in complex formation, while EDTA addition
decreased
the yield. It can also be seen here that complexes were
absent if the
reaction mixture was treated with proteinase K or
0.2% SDS, consistent
with the need for Hop1 protein to be present
and in native
conformation. Addition of dithiothreitol decreased
binding, but it is
unknown whether this reflects an effect on
zinc ion chelation caused by
modifying the cysteine residues.
Addition of ATP caused a decreased
mobility of the complex, especially
at higher Mg
2+ levels,
but much of the label failed to migrate beyond the gel
pocket,
suggesting the formation of an insoluble aggregate of
unknown nature.
Finally, although addition of NaCl below 150 mM
had no effect, binding
decreased at higher concentrations and
was abolished at 0.5 M (Fig.
4C).
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FIG. 4.
Characterization of binding of Hop1 protein to G4 DNA.
Reactions were carried out in a standard assay buffer (20 µl)
containing 10 pmol of TP G4 DNA and 0.5 µM Hop1 protein, plus the
indicated additional treatments, as described in Materials and Methods.
(A) Kinetics of Hop1 protein binding to G4 DNA with no added
constituents. (B) Complex formation with G4 DNA in the absence or
presence of zinc (0.1 mM), EDTA (5 mM), dithiothreitol (DTT; 10 mM),
ATP (5 mM), MgCl2 (10 mM), proteinase K (0.2 mg/ml), or SDS
or glycerol at the indicated concentrations. (C) Effect of NaCl added
at the indicated concentrations. TP(G4) and M denote G4 DNA prepared
from TP oligonucleotide and its unfolded constituent monomer,
respectively.
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RecA proteins and histone H1 do not display stable G4 DNA
binding.
It had previously been shown that certain strand exchange
proteins, including not only the RecA proteins of bacteria but also a
yeast homolog (Rad51), display significantly higher affinity for
single-stranded DNA substrates with higher GT contents (46, 47). In light of the present evidence that Hop1 displays a
preferential affinity for G4 DNA, we wished to determine whether these
strand exchange proteins might interact with their DNA substrates in a
similar manner. As a test of this possibility, the same
oligonucleotides that had been shown to bind Hop1 were also incubated
with certain RecA proteins. We tested not only RecA of E. coli but also that of M. tuberculosis, which has a
genome that is especially rich in GC content (1) and might
therefore be expected to favor this mode of interaction. However, no
bands indicative of RecA-G4 DNA complexes could be detected by gel
electrophoresis for the E. coli protein (Fig.
5A). In the presence of the M. tuberculosis RecA protein, no bands were seen within the gel,
although a small proportion of the label remained in the gel pocket,
where it presumably was bound to insoluble material. Aside from this
ambiguous result, we conclude that conditions suitable for
demonstration of Hop1-G4 DNA binding fail to provide any convincing
evidence for a similar mode of binding by RecA proteins.
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FIG. 5.
RecA proteins and histone H1 fail to form G4 DNA
complexes that are stable to electrophoresis. (A) Assays with Hop1
protein in comparison with the RecA proteins. Reactions were performed
in assay buffer (20 µl) containing 20 mM Tris-HCl (pH 7.5), 10 pmol
of 32P-labeled TP oligonucleotide (lanes 1 to 9) or its
G-quartet structure, TP G4 DNA (lanes 10 to 18), plus the proteins
indicated above each lane. Lanes 1 and 10 are controls lacking any
added protein. As a positive control, Hop1 protein was substituted at a
concentration of 50 nM (lanes 2 and 11) or 100 nM (lanes 3 and 12) in
the presence of 0.1 mM ZnCl2. Identical G4 DNA samples were
incubated with RecA protein from E. coli (EcRecA) at a
concentration of 100 nM (lanes 4 and 13), 250 nM (lanes 5 and 14), or
500 nM (lanes 6 and 15) and with that from M. tuberculosis
(mtRecA) at 100 nM (lanes 7 and 16), 250 nM (lanes 8 and 17), or 500 nM
(lanes 9 and 18) in the presence of 1.5 mM ATP and 2 mM
MgCl2. (B) Histone H1 fails to bind G4 DNA under these
conditions. Reactions were carried out with TP G4 DNA with Hop1 or
histone H1 at concentrations indicated above each lane. Samples were
separated on a 6% polyacrylamide gel and visualized by autoradiography
as described in Materials and Methods. M, unfolded TP monomer.
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Additional support for specificity in the binding of G4 DNA by Hop1
protein is evident from comparisons with binding assays
for the
positively charged chromosomal protein, histone H1, which
has
previously been shown to enhance G4 DNA formation. In this
experiment
(Fig.
5B), a fixed concentration of G4 DNA was incubated
with
increasing concentrations of either Hop1 or histone H1. Reaction
mixtures were analyzed by performing nondenaturing gel electrophoresis
and determining the mobilities of protein-DNA complexes by
autoradiography.
Figure
5B shows that low concentrations of Hop1
protein produced
shifted complexes of distinct mobilities. In contrast,
incubation
of G4 DNA with increasing amounts of histone H1, even at
60-fold-higher
concentration, did not alter the mobilities of either
G4-DNA or
its unfolded constituent
oligonucleotide.
Hop1 protein promotes the formation of G4 DNA.
Evidence
described above (Fig. 2A) had shown that Hop1 protein has a much higher
affinity for G4 DNA than for oligonucleotide that had not previously
been converted into the folded configuration. This might be interpreted
as indicating that Hop1 binds stably only to G4 DNA and that the small
amount of DNA-protein complexes seen for the unfolded control
represented binding to a subfraction of the oligonucleotide that had
formed G4 DNA spontaneously before incubation with Hop1. On the other
hand, perhaps weak Hop1-DNA interactions that are unstable to
electrophoresis might gradually have induced the formation of G4 DNA,
which thereby gained the potential for stable Hop1 binding. To explore
the latter possibility, we incubated oligonucleotide TP with increasing
concentrations of Hop1 protein and then treated the reaction mixtures
with proteinase K to remove the protein, so that the underlying DNA
configuration could be analyzed separately from binding. Nondenaturing
gel electrophoresis (Fig. 6) showed that
Hop1 protein did indeed promote the formation of stable G4 DNA in a
manner similar to that previously shown for S. cerevisiae
Rap1 (9) and for the 
subunit of Oxytricha telomere-binding protein (7).
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FIG. 6.
Hop1 protein promotes the formation of stable G4 DNA.
Reactions were performed in a standard assay buffer containing 20 mM
Tris-HCl (pH 7.5), 0.1 mM ZnCl2, and 5 pmol of
32P-labeled TP 49-mer in the absence (lane 1) and presence
of indicated concentrations of Hop1 protein or histone H1 at 30°C.
After incubation for 30 min, proteinase K was added to a final
concentration of 0.2 mg/ml and incubation was continued for an
additional 30 min. Samples were analyzed on a 6% polyacrylamide gel
and visualized by autoradiography. G4 DNA indicates the position of the
folded form, M is that of its unfolded constituent monomer, and S
denotes substrate DNA.
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Previous studies indicated that polycations and highly charged basic
proteins such as histone H1 promote stable association
of
Oxytricha telomeric DNA into dimers and tetramers involving
G quartets (
7). However, it has been noted that G4 DNA
formation
that is mediated by basic proteins occurs only at high
protein
concentrations and requires prolonged periods of incubation (90
to 180 min). To determine whether histone H1 has the capacity
to
promote the formation of G4 DNA under conditions used in this
study, TP
oligonucleotide was incubated with increasing concentrations
of histone
H1. Histone H1 failed to promote the formation of G4
DNA even at
60-fold-higher concentration than Hop1 protein (Fig.
6). Thus, folding
of oligonucleotide TP into G4 DNA conformation
appears not to be an
inherent feature of histone H1 or strand
exchange
proteins.
An experiment reported above (Fig.
5) indicates not only that the RecA
proteins fail to bind G4 DNA stably in the manner shown
for Hop1
protein but also that they are unable to induce G4 DNA
formation.
Because no stable DNA-protein complexes were formed
with the RecA
proteins (lanes 4 to 9), any free G4 DNA that might
have been induced
should have been evident on the gel without
our having to subject these
samples to proteolysis. There being
no band at the position of G4 DNA
in these lanes, we conclude
that the RecA proteins and histone H1 do
not catalyze G4 DNA formation
under these
conditions.
Methylation interference.
It has previously been shown that
folded G-quartet structures involve Hoogsteen base pairing between
guanine residues (37). To identify those guanine residues
that are important for the binding of Hop1 and for the formation of G4
DNA by Hop1 protein, methylation interference assays were carried out
using DMS as the methyl donor. Unmethylated or methylated
32P-labeled OX-1T 39-mer was incubated with increasing
concentrations of Hop1 protein. Reaction mixtures were analyzed by
nondenaturing gel electrophoresis, and the protein DNA complexes were
visualized by autoradiography. The results in Fig.
7A demonstrate that
methylation of guanine residues led to a considerable decrease in Hop1
binding to DNA. To ascertain that loss of binding did not result from random modification of the substrate and to identify the residues involved in G-quartet formation, we carried out methylation
interference assays with partially methylated DNA. Oligonucleotide
OX-1T that had been treated with DMS for 5 min was incubated with 100 or 250 nM Hop1 protein. DNAs were deproteinized by incubation with proteinase K, analyzed by nondenaturing gel electrophoresis, and visualized by autoradiography. The bands corresponding either to G4 DNA
or to the fraction that had remained in single-stranded form were
excised from the gel, and DNAs were isolated as described in Materials
and Methods. DNAs were treated with piperidine, and the cleavage
pattern was analyzed on a 20% polyacrylamide gel in the presence of 7 M urea. Figure 7B shows that guanine residues were uniformly cleaved in
the single-stranded DNA. By contrast, two tracts of guanine residues
were less efficiently cleaved in the sample corresponding to G4 DNA.
The intensities of bands corresponding to guanine residues in the 5'
end that are not involved in the formation of G4 DNA serve as internal
controls. A similar pattern of protection of guanine residues was
observed in methylation protection assays (data not shown). These
findings ascertain that the DNA species capable of binding Hop1 protein
with high affinity must contain arrays of unmethylated deoxyguanine
residues, as is the case for G4 DNA.
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|
FIG. 7.
Methylation of the N7 group of guanine modifies binding
of Hop1 protein to DNA. (A) Mobility shift assay of Hop1 protein
binding to DMS-modified and unmodified DNA. Reactions were performed in
a standard assay buffer containing 20 mM Tris-HCl (pH 7.5), 0.1 mM
ZnCl2, and 10 pmol of 32P-labeled OX-1T
oligonucleotide [either unmodified (DMS) or modified (+DMS)] in the
absence (lane 1) or presence of Hop1 protein at a concentration of 25 (lane 2), 50 (lane 3), 100 (lane 4), 250 (lane 5), or 500 nM (lane 6),
respectively. Samples were incubated and analyzed as described in the
legend to Fig. 1. M denotes the position of unfolded monomer. (B)
Methylation interference footprinting identifies the involvement of
contiguous dG residues in the formation of G quartets. Five picomoles
of partially methylated and radiolabeled OX-1T oligonucleotide was
incubated with 100 nM Hop1 protein at 30°C for 30 min and then deproteinized by incubation with proteinase K
(0.2 mg/ml) for 30 min at 30°C. G4 DNA and single-stranded DNA were
then separated by polyacrylamide gel electrophoresis as described in
the legend to Fig. 6 and isolated from the gel. Aliquots of these
isolates were treated with piperidine, subjected to the Maxam-Gilbert
chemical sequencing reaction, and analyzed on a polyacrylamide gel in
the presence of 7 M urea as described in Materials and Methods.
Single-stranded DNA (lane 3) and G4 DNA (lane 4) isolates display
differential intensities of G-specific cleavage in the poly(dG)
segments. Control aliquots of the single-stranded DNA (lane 1) and G4
DNA (lane 2) samples were not treated with piperidine. The aliquot in
lane 5 was treated identically to that in lane 4 except the G4 DNA was
formed by incubation with 250 nM Hop1 protein. (C) Summary of
methylation interference and cleavage pattern. The guanine residues
involved in G-G Hoogsteen base pairing are boxed, while those residues
that are not involved are circled.
|
|
| |
DISCUSSION |
Hop1 protein is known from genetic analysis to play a crucial role
in meiotic synapsis (11, 17). In this study, we have explored the possibility that the interaction of Hop1 with chromosomal DNA involves its specific affinity for G4 DNA. We have found not only
that oligonucleotides capable of forming G quartets are most effectively bound by Hop1 protein but also that preformation of G4 DNA
strongly enhances binding. These findings suggest that the crucial
function of Hop1 in yeast meiosis involves its interaction with G4 DNA.
Previous studies have suggested a role for G4 DNA in meiotic synapsis.
Sen and Gilbert (37) demonstrated that four identical molecules containing stretches of guanine residues could be stably joined in parallel by the formation of G quartets between them. On this
basis, they made the intriguing suggestion that meiotic synapsis might
entail the joining of the chromatids to one other in this manner.
Although their model focused on the possibility that G4 DNA would join
all four chromatids, the ability of oligonucleotides containing two or
more guanine repeats to form G4 DNA by dimerization (such as several of
the oligonucleotides used in this work) raises the possibility that
pairs of duplexes with neighboring repeats would be joined to each
other. Later studies have revealed that the product of the
KEM1/SEP1 gene acts as a DNase with specificity toward G4
DNA, thus suggesting that Kem1/Sep1 serves to process G4 DNA formed
earlier in meiotic prophase (22). Detailed phenotypic analysis has revealed a pachytene-phase arrest in kem1/sep1
mutants, indicating that hydrolysis of G4 DNA may be required for
further progression through meiosis (45). Furthermore, there
was a striking incidence of nonhomologous synapsis in these mutants,
perhaps indicative of a requirement for Kem1/Sep1-mediated DNA
hydrolysis in the desynapsis of mispaired chromatids. Together, these
findings favor the possibility that G4 DNA plays a crucial role in
meiotic synapsis and recombination.
How might the Hop1 protein and G4 DNA act together to promote synapsis?
A full understanding will require direct analysis of G4 DNA in meiotic
cells, but certain possible roles can be inferred from the mutant
phenotypes and cytological analysis. The HOP1,
RED1, and MEK1 genes define a single epistasis
group, as multiple mutants for these genes generally reduce
recombination to about the same extent as individual mutants
(32). These findings suggest that the products of all three
genes collaborate in executing a common function, and phenotypic
analysis indicates that this function is important for proper synapsis
and crossing over between homologs. Immunochemical staining reveals
that Hop1 and Red1 colocalize discontinuously along the chromosomes
early in synapsis, with the Red1 staining pattern progressively
coalescing into a more nearly continuous array along each bivalent as
Hop1 is progressively lost (40). The specificity of genetic
interactions between HOP1 and RED1 suggests a
direct interaction between the proteins (8, 13), as
confirmed by two-hybrid experiments (13). Since Hop1 is a
DNA-binding protein with specificity for G4 DNA sequences, we feel it
likely that Hop1 binds directly to the chromatids via this interaction
(perhaps also playing a role in the formation of G4 DNA) and later
dissociates from the DNA in a manner that leaves Red1 interactions intact.
There appear to be at least two classes of DNA transactions that might
well depend on G4 DNA and involvement of Hop1 protein (Fig.
8): (i) broad-scale interactions along
the length of intact duplexes and (ii) more specific functions involved
in the formation or processing of DSBs. With regard to the former, it
has been argued convincingly (18, 32) that homologous
chromatids interact rather nonspecifically along their length prior to
the establishment of the sequence-specific interactions involved in
gene conversion and crossing over. Since DNA normally is negatively
supercoiled in vivo (50) and Hop1 preferentially binds DNA
of this type (17), we suggest that Hop1 interacts with
underwound duplex DNA in G-rich regions and mediates the folding of
appropriate segments into G quartets, some of which may interconnect
homologous duplexes. Alternatively, the duplex DNA may transiently
become single-stranded during a genome-wide search for homologous
sequences, thereby contributing to the formation of G4 DNA. Consistent
with this notion, there is evidence for the unwinding of heterologous and homologous duplex DNA during search for homology by E. coli RecA protein (33). A prevalence of such
interactions might preferentially align homologous segments due to the
identity in their patterns of G-rich sequences. Alternatively,
homologous alignment of this sort might serve to maintain juxtaposition
of sister chromatids, thereby providing a structural basis for
distinguishing the sister duplex from either homolog as a precondition
for the preferential exclusion of sister chromatid crossovers (18,
32).
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|
FIG. 8.
Hypothetical mechanism of formation and/or stabilization
of G4 DNA by Hop1 protein. In the model, bold and light DNA molecules
represent homologs and closed circles denote guanine residues. Once a
DSB is produced at a hot spot by Spo11 endonuclease, the free ends are
resected by exonuclease and/or helicase activities to generate a 3'
overhang. Subsequently, Hop1 protein, by binding to the guanine repeats
in the 3' overhang and to the G-rich strand in the partially unwound
homologous duplex DNA, promotes the formation of intermolecular G4 DNA.
Alternatively (right side), interstitial interactions between
chromatids could be mediated by the formation of intermolecular G-G
pairing, regardless of whether the flanking nucleotide sequences are
homologous. We suggest that such interactions might either join
homologs (as diagrammed here) to facilitate interhomolog recombination
or join sister chromatids in a manner that delimits sister chromatid
exchange.
|
|
A second set of Hop1 interactions with G4 DNA might serve more
specifically in DSB repair and recombination. It has been reported that
DSBs are reduced in number and delayed in appearance in hop1 meiosis (18). This might mean that Hop1-dependent
interhomolog interactions of the type discussed above serve to promote
DSB formation, especially in G-rich regions that define the G isochores where DSBs are prevalent (3, 14, 34). On the other hand, it
is difficult to exclude the possibility that DSBs actually were being
formed at the usual rate but were short lived in the absence of Hop1
function, as might have been the case if the stability of unresected
DSBs in rad50S meiosis depends on HOP1. A failure to modulate resection appropriately may lead to extensive
exonucleolytic attack on both 5' and 3' ends, producing a greatly
expanded gap that might then be repaired from the sister chromatid.
This could hinder interhomolog recombination and leave no genetic
signal other than the possible excision of duplications
(18). Circumstantial evidence favoring a role for Hop1 in
DSB processing is seen in the aforementioned finding (17)
that exonucleolytic attack on linearized duplex DNA in nuclear extracts
is blocked by addition of purified Hop1. The preferential binding of
Hop1 to duplex DNA relative to single-stranded DNA (17)
might permit its rapid assembly on the duplex directly adjacent to the
single-stranded tail being generated by resection, possibly by forming
G quartets and/or associating with them in a manner that would inhibit
further resection. Accordingly, a possible explanation for the
prevalence of G isochores in the vicinity of recombinational hotspots
(3) is that the flanking DNA must contain sufficient guanine
repeats to aid in a resection-limiting action of this sort.
Additionally, G4 DNA formed within the single-stranded tail and bound
by Hop1 might play a direct role in searching for the homolog and
promoting strand invasion. Regarding the free ends of chromosomal DNA
molecules, it should also be noted that telomeres, which are especially
rich in sequences capable of G4 DNA formation, probably play an
important role in synapsis (31), providing yet another
potentially important substrate for interaction with Hop1 protein.
Recent studies have shown that ATP-dependent strand exchange proteins,
such as the prototypic RecA protein and its homolog Rad51, interact
preferentially with GT-rich DNA (46, 47), and we found in
this study that this affinity is independent of G4-DNA. In contrast,
the binding of G-rich DNA by Hop1 protein appears to reflect the
ability of the DNA to adopt the G4 DNA conformation by a mechanism that
does not require ATP. Despite these distinctive modes of interaction
with chromosomal DNA during meiosis, both RecA-like proteins and Hop1
perform their complementary functions in meiotic recombination within
G-rich DNA. It therefore seems possible that an individual
recombination event entails the successive interactions of the same
guanine residues with each class of protein. The probable significance
of G4 DNA to recombination is also underscored by the demonstration
that LR1, a B-cell-specific DNA-binding factor, interacts specifically
with sequences capable of forming G4 DNA in the region undergoing Ig switch recombination (6). In the future, a more detailed
analysis of how Hop1 protein interacts with chromosomal DNA in vivo may help to elucidate the role of G4 DNA in meiotic synapsis and recombination.
| |
ACKNOWLEDGMENTS |
We thank Mary Kironmai, Moreshwar Vaze, and R. Ajay Kumar for
generous gifts of purified Hop1 and RecA proteins used in the initial
stages of this study.
This research was supported by a fellowship from the American Cancer
Society, Yamagiwa-Yoshida fellowship (administered by UICC, Geneva,
Switzerland), a grant from the Department of Science and Technology,
New Delhi, to K.M., and an NIH grant (GM-18541) to B.B.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Genetics, Box 357360, University of Washington, Seattle, WA 98195-7360. Phone: (206) 543-9068. Fax: (206) 543-0754. E-mail:byers{at}genetics.washington.edu.
| |
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Abstract
Introduction
