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Molecular and Cellular Biology, June 2000, p. 4224-4237, Vol. 20, No. 12
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Interference Footprinting Analysis of Telomerase
Elongation Complexes
Sima
Benjamin,
Nava
Baran, and
Haim
Manor*
Department of Biology, Technion-Israel
Institute of Technology, Haifa 32000, Israel
Received 3 February 2000/Returned for modification 13 March
2000/Accepted 27 March 2000
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ABSTRACT |
Telomerase is a reverse transcriptase that adds single-stranded
telomeric repeats to the ends of linear eukaryotic
chromosomes. It consists of an RNA molecule including a template
sequence, a protein subunit containing reverse transcriptase motifs,
and auxiliary proteins. We have carried out an interference
footprinting analysis of the Tetrahymena
telomerase elongation complexes. In this study,
single-stranded oligonucleotide primers containing telomeric sequences were modified with base-specific
chemical reagents and extended with the telomerase by a
single 32P-labeled dGMP or dTMP. Base modifications that
interfered with the primer extension reactions were mapped by
footprinting. Major functional interactions were detected between the
telomerase and the six or seven 3'-terminal residues of the
primers. These interactions occurred not only with the RNA template
region, but also with another region in the enzyme ribonucleoprotein
complex designated the telomerase DNA interacting surface
(TDIS). This was indicated by footprints generated with dimethyl
sulfate (that did not affect Watson-Crick hydrogen bonding) and by
footprinting assays performed with mutant primers. In primers aligned
at a distance of 2 nucleotides along the RNA template region, the
footprints of the six or seven 3'-terminal residues were shifted by 2 nucleotides. This shift indicated that during the elongation reaction,
TDIS moved in concert with the 3' ends of the primers relative to the
template region. Weak interactions occurred between the
telomerase and residues located upstream of the seventh
nucleotide. These interactions were stronger in primers that were
impaired in the ability to align with the template.
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INTRODUCTION |
Telomeres, the structures at the
ends of linear eukaryotic chromosomes, consist of short DNA sequence
repeats associated with specific DNA-binding proteins. In most
eukaryotes, the telomeric DNA includes clusters of G
residues and the complementary clusters of C residues that are
interspersed with other short repeats (for reviews, see references
9 and 60). The G-rich strand,
which is oriented in a 5' 
3' direction towards the ends of the
chromosomes, protrudes as a single-stranded overhang that may interact
with the double-stranded telomeric sequences (27, 35,
40, 43, 57, 58).
Telomerase, an enzyme found in most eukaryotes, is a reverse
transcriptase (RT) that adds telomeric repeats to the
G-rich extensions, thereby preventing chromosome shortening due to the inability of the normal replication apparatus to complete telomere synthesis (13, 23, 24). All telomerases
characterized so far contain an RNA molecule and a catalytic protein
subunit. The telomerase RNA of each organism includes a
short sequence, complementary to the telomeric repeats of
this organism, which serves as a template for synthesis of these
repeats (10, 18, 26, 41, 54). The secondary structure of the
RNAs of the ciliate telomerases has been conserved
throughout evolution (41, 52). It is still not clear whether
the telomerase RNA secondary structures in other groups of
organisms have been similarly conserved. The catalytic protein subunit
in all telomerases characterized so far includes reverse
transcriptase motifs and was therefore termed telomerase RT
(TERT) (17, 32, 42, 47, 49). The activities of ciliate and
human telomerases can be reconstituted in vitro by mixing the TERT of each of the enzymes with the corresponding RNA subunit (1, 3, 5, 14). However, genetic and biochemical experiments have indicated that telomerases may also contain other
auxiliary protein subunits (7, 16, 31, 34, 51).
The ciliate Tetrahymena thermophila telomerase
was the first telomerase to be discovered (23,
24). The template sequence in the RNA of this
telomerase was mapped and found to be 3'-CCCCAAC-5', encoding the Tetrahymena telomeric repeat
5'-(GGGGTT)n-3' (2, 19, 21,
26). In addition, A residues next to the 3' end of the template
region were found to be required for proper alignment of the primer
along the template (19). Evidence was also provided for the
involvement of other regions of the RNA in the primer extension process
(8, 20, 39).
In vitro, primer extension by the Tetrahymena
telomerase is processive (22). This processive
mechanism requires that after completion of the synthesis of each
repeat, the 3' end of the primer be translocated to the beginning of
the template region without complete dissociation of the primer-enzyme
complex (15, 22, 37, 38). Therefore, it has been suggested
that, in addition to the catalytic site, the telomerase
must contain a second site that serves as an anchor to which the primer
remains bound during the translocation step (15, 38). The
existence of a second site was also suggested by experiments in which
either the Tetrahymena telomerase or the human
enzyme was used to extend primers that did not contain
telomeric repeats at their 3' termini but contained G-rich
sequences at their 5' termini. These primers were efficiently extended
by the two telomerases, whereas primers that contained no
G-rich sequences were rather poor substrates for the enzymes. Hence, it
has been proposed that the second site preferentially binds G-rich
sequences (33, 48; see also reference
7).
The interactions between the Tetrahymena enzyme and the DNA
primers were also investigated by UV cross-linking techniques. In two
studies, DNA primers substituted with the thymidine analog 5-[N-(p-azidobenzoyl)-3-aminoallyl]-deoxyuridine]
(N3RdU) or with 5-iodouracil were found to
specifically cross-link to 100- and 95-kDa proteins that
copurified with the Tetrahymena
telomerase activity (16, 30). In another study
performed with the telomerase of the ciliate
Euplotes aediculatus, DNA primers substituted with 5-iodopyrimidines were found to cross-link with a 130-kDa protein subunit and the RNA subunit of the enzyme (29). In this
study, the cross-links were mapped to nucleotides located 20 to 22 bases upstream of the 3' ends of the primers. From these data, it has been proposed that the upstream nucleotides were cross-linked to the
anchor site of the enzyme (29).
Here we present an interference footprinting analysis designed to map
functional interactions between the Tetrahymena
telomerase and single-stranded DNA primers containing
telomeric repeats during the elongation phase of primer
extension reactions. In this study, major interactions were detected
between the telomerase and the six or seven 3'-terminal
nucleotide residues in the primers. The data indicated that these
interactions occur not only with the RNA template region, but also with
another region in the telomerase ribonucleoprotein complex
(RNP). Furthermore, these two regions were found to move relative to
each other during the elongation reaction. Only weak interactions were
observed in most primers between the enzyme and nucleotide residues
located upstream of the seventh nucleotide. These interactions were
stronger in elongation complexes formed with mutant primers that were
impaired in the ability to align with the template. We discuss the
results in relation to previous studies of telomerases and
other polymerases.
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MATERIALS AND METHODS |
Oligonucleotides.
DNA oligonucleotides were purchased from
Biotechnology General (Nes Ziona, Israel) and purified by
polyacrylamide gel electrophoresis, followed by Sephadex G-50 spun
column chromatography (53). Prior to being modified or
extended by telomerase, the oligonucleotide samples were
heated for 5 min at 100°C and then fast cooled to 4°C.
Preparation of telomerase.
T. thermophila
cells were grown to late logarithmic phase and starved without
subsequent mating, as described before (25, 30). Partially
purified telomerase was prepared as follows, using a
published procedure that has been modified slightly (21). An
S100 extract was prepared and bound to DEAE-Sepharose Fast Flow beads
(Sigma) that had been washed with TMGI buffer (10 mM Tris-HCl [pH
8.0], 1 mM MgCl2, 10% glycerol, 5 mM mercaptoethanol, 0.10 mM phenylmethylsulfonyl fluoride, 0.25 µg of pepstatin per ml,
0.25 µg of chymostatin per ml) that also contained 0.20 M sodium
acetate. Binding was accomplished by suspending the beads in the
extract dissolved in TMGI buffer containing 0.20 M sodium acetate and
10 U of RNasin (Promega) per ml and by swirling the suspension for 30 min at 4°C. The mixture was centrifuged in a Heraeus centrifuge for 2 min at 500 × g at 4°C, and the beads were
resuspended in TMGI buffer containing 0.20 M sodium acetate. The
resuspended beads were washed and centrifuged again as described above,
then resuspended in the same buffer, and poured into a column. The
column was washed with 5 volumes of TMGI buffer containing 0.20 M
sodium acetate, and telomerase activity was eluted with 2 volumes of TMGI buffer containing 0.50 M sodium acetate. This eluent
was loaded on an Octyl-Sepharose CL-4B column (Pharmacia). The column
was washed with 5 volumes of TMGI buffer containing 0.50 M sodium
acetate and with 5 volumes of TMGI buffer. Telomerase was eluted with
TMGI buffer containing 1% Triton X-100. Pooled fractions containing
the enzyme were frozen and stored at 
80°C.
Primer extension by telomerase.
Primer extension
was carried out in 20-µl reaction mixtures containing 50 mM Tris-HCl
(pH 8.0), 2 mM MgCl2, 0.1 M sodium acetate, 1 mM
spermidine, 6 mM mercaptoethanol, 0.4 U of RNasin per ml, 1 µM
[
-32P]dGTP (specific radioactivity, 300 Ci/mmol;
Dupont NEN, Boston, Mass.), 100 µM dTTP, 2.4 µM primer, and 5 to 10 µl of telomerase. The reaction mixtures were incubated
for 15 min at 30°C. Primer extension by a single G residue was
carried out in the same buffer except that dTTP was omitted from the
reaction mixtures and the concentration of [-32P]dGTP
was 0.1 µM (specific radioactivity, 3,000 Ci/mmol). These reaction
mixtures were incubated for 15 min at 10°C. Primer extension by a
single T residue was performed similarly except that the 0.1 µM
[-32P]dGTP was replaced with 0.3 µM
[-32P]dTTP (specific radioactivity, 3,000 Ci/mmol).
All reactions were terminated by addition of EDTA, sodium dodecyl
sulfate (SDS), and proteinase K at final concentrations of 15 mM,
0.08%, and 0.05 mg/ml, respectively, and the mixtures were incubated
for 45 min at 45°C. Next, ammonium acetate and yeast tRNA were added at final concentrations of 2.5 M and 15 µg/ml, respectively, and the
reaction products were precipitated with ethanol and washed with 70%
ethanol, as previously described (4). Samples were electrophoresed either in 10% polyacrylamide sequencing gels (products obtained in reactions performed in the presence of both dGTP and dTTP)
or in 12% polyacrylamide sequencing gels (products obtained in
reactions performed in the presence of either dGTP or dTTP). The gels
were dried and exposed to phosphorimaging screens that were
subsequently scanned with a Molecular Dynamics PhosphorImager.
Modification of DNA by chemical reagents. (i) Modification by
DMS.
DNA at a concentration of 15 µg/ml was exposed to dimethyl
sulfate (DMS) for 10 min at 10°C at the concentrations specified in
Fig. 3. The reactions were terminated by the addition of
mercaptoethanol at a final concentration of 1.0 M.
(ii) Modification by formic acid.
DNA at a concentration of
50 µg/ml was exposed to formic acid for 30 min at 37°C at the
concentrations specified in the figures. The reactions were terminated
by the addition of sodium acetate and Trizma base at final
concentrations of 0.8 M and 0.5 M, respectively.
(iii) Modification by KMnO4.
DNA at a
concentration of 50 µg/ml was exposed to potassium permanganate
(KMnO4) at the specified concentrations for 20 min at
37°C. The reactions were terminated by the addition of
mercaptoethanol at a final concentration of 1.0 M. After completion of
the reactions, all samples were precipitated with ethanol in the
presence of 0.30 M sodium acetate and washed twice with 70% ethanol,
as described above.
Interference footprinting.
Oligonucleotide primers were
modified by one of the three reagents. For the modifications, samples
of each oligonucleotide were exposed to several concentrations of the
modifying reagent or not exposed at all. The modified DNAs were
extended with telomerase by using a single
32P-labeled dGMP or dTMP, as described above. However,
60-µl reaction mixtures were used for these assays. The reactions
were terminated by the addition of EDTA, SDS, and proteinase K and
incubated as described above. Subsequently, the samples were extracted
once with an equal volume of a mixture of phenol and chloroform (1:1), precipitated, and washed with 70% ethanol. In the control assays, the
DNA was first labeled and then chemically modified. All the DNA samples
were dried, exposed to piperidine (44), and analyzed by
electrophoresis in 16% Long Ranger (FMC) gels containing 7 M urea, as
described before (4). All footprinting assays were performed
at least twice at several concentrations of the reagents (see the
legends to the figures), and the results were reproducible.
Quantitative analysis of the footprinting data.
One control
lane and the corresponding experimental lane, in which the modification
apparently followed single-hit kinetics, were selected for quantitative
analysis. Quantification of the bands observed in each gel was
performed with the software supplied with the Molecular Dynamics
PhosphorImager. Corrections for differential losses during the
procedure were performed by first calculating the sum of the
intensities of all the bands in each lane j,
(
Ii)j; then the
observed intensity of each band, Ii, within a
lane j was multiplied by the ratio
(Ii)m/(Ii)j,
where (Ii)m was the
largest sum. The corrected intensity of each band in a sample that has
not been exposed to the reagent (e.g., 0% formic acid),
I0', was subtracted from the corrected intensity
of the corresponding band in a selected experimental lane,
Ie'. Similarly, I0 was
subtracted from the corresponding control lane value,
Ic'. The differences were divided to give the
relative interference values, (Ie' I0')/(Ic' I0'). These ratios were normalized relative to the
highest ratio, which was given the value 1.0, and plotted as histograms
that are presented in Fig. 3 to 7.
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RESULTS |
Primer extension by telomerase.
Table
1 shows nine of the oligonucleotide
primers used for our footprinting analysis. Eight of these
oligonucleotides (oligos tel1 to tel8) ended with the sequence GGG-3'.
As Fig. 1A shows, these oligonucleotides
were expected to align with the telomerase RNA template
region so that G would be the first nucleotide added to them by the
enzyme. The ninth (oligo tel9) ended with the sequence GGGGT-3' and was
expected to align with the template as shown in Fig. 1B, so that T
would be the first residue added to it by the enzyme. Figure
2A shows assays in which two of the
primers that ended with GGG-3', oligo tel1 and oligo tel6, were
extended in the presence of 32P-labeled dGTP and unlabeled
dTTP. It can be seen that typical telomerase extension
products containing many Tetrahymena telomeric repeats were obtained (lanes 1 and 3). Furthermore, RNase inhibited these reactions, indicating that the extension was catalyzed by telomerase and not by contaminating polymerases (lanes 2 and 4) (24, 25). Figure 2B (lanes 1 and 3) shows experiments
in which the same primers were extended in the presence of
32P-labeled dGTP alone. Unlike the assays shown in Fig. 2A
that were performed at 30°C, these assays were carried out at 10°C. At this lower temperature, the nuclease activity of the
telomerase (15, 45) or the activities of other
possible contaminating nucleases were found to be minimized (H. Wang
and E. H. Blackburn, personal communication; S. Benjamin, N. Baran, and H. Manor, unpublished data). As expected, the major products
obtained in these reactions were primers extended by a single
32P-labeled dGMP residue; only relatively small amounts of
shorter products were generated by nucleolytic cleavage followed by
reinsertion of radioactively labeled dGMP residues. These reactions
were also inhibited by exposure of the enzyme to RNase (Fig. 2B, lanes
2 and 4), an indication that the extended primers, like the products of
the reactions shown in Fig. 2A, were authentic telomerase
extension products. Similar assays were performed with all the other
primers and gave similar results. It should be noted that in primer
extension reactions performed at 10°C in the presence of both
32P-labeled dGTP and unlabeled dTTP, the primers were
extended by many telomeric repeats, like those in the
reactions performed at 30°C (not shown).
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TABLE 1.
Oligonucleotide primers used for the interference assays
and relative incorporation of a single [32P]dGMP
residue into oligos tel1 through tel8
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FIG. 1.
Schematic representation of the alignment of
oligonucleotide primers with the Tetrahymena
telomerase RNA template region and extension of these
primers by a single nucleotide residue. (A) Scheme showing the
alignment of primers ending with the sequence GGG-3' along the
telomerase RNA template region and their extension by a
single 32P-labeled dGMP residue (g*). (B) Scheme showing
the alignment of primers ending with the sequence GGGGT-3' along the
telomerase RNA template region and their extension by a
single 32P-labeled dTMP residue (t*).
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FIG. 2.
Elongation of oligonucleotide primers by the
telomerase. (A) Primer extension reactions were carried out
with the telomerase at 30°C in the presence of
32P-labeled dGTP and unlabeled dTTP, as described in
Materials and Methods (lanes 1 and 3). Similar reactions were performed
with telomerase that had been treated with 0.50 U of RNase
A per ml for 15 min at 22°C (lanes 2 and 4). The products were
electrophoresed in denaturing polyacrylamide gels, and the gels were
dried and visualized in a Molecular Dynamics PhosphorImager. nt,
nucleotides. (B) Same as panel A except that the reactions were
performed at 10°C in the absence of dTTP.
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Table
1 also shows a quantitative analysis of the incorporation of
32P-labeled dGTP into the oligos tel1 to tel8, based on
data of
the type shown in Fig.
2B. The data were normalized relative to
the incorporation into oligo tel1, which was set at 100. It can
be seen
that the normalized incorporation into the oligonucleotides
varied
between 5.3 ± 2 and 173 ± 54. The significance of these
variations will be discussed
below.
Interference footprinting of elongation complexes generated with
oligo tel1, which contains telomeric repeats at the 3' and
5' ends.
Interference footprinting was used to study the
interactions between individual primer residues and the
telomerase in elongation complexes during extension of the
primers by a single nucleotide. Footprinting assays were initially
performed with the 21-residue oligo tel1, which consisted of
telomeric repeats at the 3' and 5' ends separated by a
nontelomeric sequence (Table 1). These assays were
designed to assess the interactions of the enzyme with the
telomeric repeats at the two separate positions. The procedure was as follows. Oligo tel1 molecules were first modified with
each of the three base-specific chemical reagents DMS, formic acid, and
KMnO4. The modified primers were incubated with
telomerase in the presence of [32P]dGTP so
that the chains were extended by a single 32P-labeled dGMP
residue. Thus, the primers were end labeled at the 3' termini. DNA was
subsequently purified, cleaved at the modified sites by treatment with
piperidine, and electrophoresed in denaturing gels. In control assays
that were performed in parallel, the primer molecules were first
extended by a single 32P-labeled dGMP residue, then
chemically modified, treated with piperidine, and electrophoresed in
the same gels. The gels were exposed to PhosphorImager screens.
Figure
3A, panel I, shows PhosphorImager
traces of footprints obtained after modification of oligo tel1
molecules with three
concentrations of DMS, a reagent that methylates
the N-7 atoms
of guanine residues and also the N-1 and N-3 atoms of
adenine
residues at much lower efficiencies. A comparison between the
experimental and the control lanes indicated that modification
of
residues G2, G3, and G6 strongly interfered with the primer
extension
by telomerase. These footprints also indicated that
modification of the G residues upstream of G6, including the residues
constituting the 5' telomeric repeat, did not substantially
interfere
with the primer extension. It should be noted that in these
assays
and in most subsequent assays, the G1 band was not resolved well
from the band containing the unincorporated dGTP and hence could
not be
analyzed. However, in some assays (not shown), the G1 cleavage
product
was better resolved, and modification at this residue
was also found to
strongly interfere with the extension of the
primer. The primer
residues G1, G2, and G3 must form Watson-Crick
hydrogen bonds with the
telomerase RNA-templating residues C47,
C48, and C49 (Fig.
1). However, these interactions should not
have been affected by
modification with DMS. Hence, the interference
patterns described above
are indicative of additional interactions
of G1, G2, and G3 with other
components of the telomerase ribonucleoprotein
(RNP).
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FIG. 3.
Interference footprinting performed with oligo tel1,
which contains telomeric sequences at the 3' and 5' ends.
(A) Interference footprinting was performed with oligo tel1, whose
sequence is shown at the bottom of the figure, using the procedure
described in Materials and Methods. The telomeric repeats
in the oligo tel1 sequence are indicated with boldface letters. The
concentrations of the reagents used for these assays, DMS (panel I),
formic acid (panel II), and KMnO4 (panel III), are
indicated. Pr, unincorporated 32P-labeled dATP. (B)
Quantitative analysis of the data shown in A was performed as described
in Materials and Methods. The histograms present data obtained in the
analysis of one lane from each interference assay and of a
corresponding control lane, namely the 0.3% DMS, 2.5% formic acid,
and 0.1 mM KMnO4 lanes. The relative interference values
are shown as bars. For calculations of the interference resulting from
modification of T4 or T5, the molecules modified at T4 and T5 were
assumed to be equally labeled (see Results).
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A second reagent used for these experiments, formic acid, causes
removal of both guanine and adenine bases from the DNA backbone.
Figure
3A, panel II, shows the PhosphorImager traces of assays
performed with
formic acid at four concentrations. These assays
too indicated that
modification of residues G2, G3, and G6 strongly
interfered with primer
extension by the telomerase. As already
found in the assays
performed with DMS, modifications of other
upstream residues did not
appear to substantially affect the extension
of the modified
primers.
A third reagent, KMnO
4, oxidizes the double bond between
the atoms C-5 and C-6 of thymine and causes disruption of the ring
structure. Figure
3A, panel III, shows interference footprinting
assays
performed with KMnO
4 at three different concentrations.
In
these footprints and in other footprints shown below, residues
T4 and
T5 were not resolved. Clearly, the intensity of the combined
T4 plus T5
band in the interference assays is considerably lower
than that of the
corresponding band in the control assays. The
KMnO
4
interference patterns are discussed further
below.
Of the data shown in Fig.
3A, the footprints obtained with one
concentration of each reagent were quantitated and used to
calculate
the relative interference due to modification of each
residue in the
primer, as described in Materials and Methods.
Figure
3B shows a
graphic representation of these data. Each bar
represents the
normalized ratio of the intensity of a band in
the experimental lane
and the intensity of the corresponding band
in the control lane. The
lower the bar, the higher the degree
of interference caused by
modification of the nucleotide corresponding
to this band. It can be
seen that modifications of each of residues
G2, G3, and G6 by formic
acid, interfered with the elongation
of oligo tel1 to an extent of
75% relative to the elongation
of molecules in which residue G17 was
modified. In other experiments
performed with oligo tel1 and various
derivatives of this oligonucleotide,
the extents of interference caused
by modifications of nucleotides
G2 and G3 were as high as 98% (see
below). Figure
3B also shows
that moderate interference was caused by
modification of residue
G7 with formic acid. Modifications of the
residues upstream of
G7 did not substantially affect the extension of
the modified
primer. Modifications of residues G2, G3, G6, and G7 by
DMS caused
a somewhat reduced interference. This could be due to the
difference
in the modification products generated by exposure to these
two
reagents. Otherwise, the DMS and formic acid interference profiles
were
similar.
In the quantitation of the KMnO
4 data, the interference due
to T4 modification was assumed to be equal to the interference
due to
T5 modification. In another experiment (not shown), oligo
tel1 was
5'-end labeled, modified with KMnO
4, and cleaved with
piperidine. In gel electrophoresis of these cleavage products,
T4 and
T5 were resolved and found to be equally modified. Hence,
the
interference due to modification of either residue T4 or residue
T5 was
determined by dividing the intensity of the combined T4
plus T5 band in
the interference lane by that of the corresponding
band in the control
lane. It is apparent that modification of
either T4 or T5 strongly
inhibited primer
extension.
It should be noted that even though the interference profiles obtained
in the assays performed with the three modifying reagents
are
correlated, each of the profiles should be assessed separately;
for the
various modifications caused by the three reagents could
affect the
reaction in different ways and might cause different
degrees of
interference.
Interference footprinting of complexes generated with oligo tel1
variants containing substitutions at the 3' telomeric
repeat. (i) Interference footprinting of complexes generated with
primers in which residues facing nucleotides 50 and 51 of the RNA
subunit were replaced.
As Figure 1A shows, of the residues
5'-TTGGG-3' in oligo tel1, nucleotides G1, G2, and G3 must
form Watson-Crick hydrogen bonds with the telomerase RNA
nucleotides C47, C48, and C49, which serve as templating residues
(2, 19, 21). Nucleotides T4 and T5 may also form
Watson-Crick hydrogen bonds with telomerase RNA nucleotides
A50 and A51. These RNA nucleotides were found to be required for
alignment of telomeric primers along the template, even
though they do not serve as templating residues (19). The following experiments were designed to examine the relative
contributions of the Watson-Crick pairings between T4 and A50 and
between T5 and A51 vis-à-vis other interactions required for a
proper alignment of the primers. For this purpose, interference
footprinting analyses were performed with primers in which the T4 and
T5 residues were replaced with other nucleotides.
We first used for these assays oligo tel2, which contains a
telomeric repeat at the 5' terminus and a 3'
telomeric sequence
that has been mutated by replacing
residue T4 with A. As Table
1 shows, only about 5% as much
radioactively labeled dGMP was
incorporated into this primer as into
oligo tel1. This result
supports the notion that Watson-Crick pairing
with RNA residue
A50 plays a major role in the primer extension
reaction (
19).
Figure
4A shows
a footprinting analysis of this low-efficiency
reaction. Formic acid
rather than DMS was used for these and subsequent
assays reported below
because it gave more reproducible results
and provided reliable
interference patterns for A as well as G
residues. Panel I shows one
control lane (c) and the corresponding
experimental (i) lane that were
selected from a whole experiment
of the type shown in Fig.
3. Panel II
shows a histogram of the
relative interference values calculated from
the data shown in
panel I. It can be seen that modification of residues
G2, G3,
and A4 strongly interfered with the extension of this primer
and
that modification of G6 also resulted in a rather strong
interference.
The strong relative interference resulting from
modification of
nucleotide A4, which cannot form a Watson-Crick
hydrogen bond
with A50 of the telomerase RNA, showed that
the extension of oligo
tel2 depended on interactions other than
Watson-Crick base-pairing
with A50. It should also be noted that,
unlike the footprints
of oligo tel1, modification of the G residues in
the upstream
telomeric repeat of oligo tel2 did cause a
rather strong interference
with its extension. These data indicated
that the interactions
of the upstream G's with the
telomerase were functionally significant
for this
inefficient reaction (see Discussion).
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FIG. 4.
Interference footprinting assays performed with oligo
tel1 variants containing substitutions of residues N4 and N5. Formic
acid (FA) and KMnO4 interference assays were carried out as
described in the legend to Fig. 3. For each reagent, one control lane
(c) and one experimental lane (i) are shown in panel I, and the
corresponding histograms are presented in panel II. (A) Formic acid
(10%) assays of oligo tel2. (B) Formic acid (10%) assays and 0.15 mM
KMnO4 assays of oligo tel3.
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We next studied the extension of oligo tel3, in which residue T5 rather
than T4 was replaced with A. As Table
1 shows, the
efficiency of
extension of this primer was only about twofold
lower than that of
oligo tel1. This result is compatible with
a previous observation that
formation of a Watson-Crick base pair
between residue N5 in the primer
and residue A51 in the RNA template
is less essential for the extension
reaction than formation of
a base pair between residue N4 in the primer
and A50 in the template
(
19). Figure
4B shows interference
footprinting assays performed
with this oligonucleotide, using formic
acid and KMnO
4. It can
be seen that modifications of
residues G2, G3, and A5 strongly
interfered with the extension of the
primer, whereas the interference
due to modifications of residues G6
and G7 was more moderate.
The strong interference caused by
modification of A5 indicates
that interactions other than Watson-Crick
base-pairing between
the N5 nucleotide in the primer and RNA residue
A51 played a major
role in extension of this primer by the enzyme. It
should also
be noted that modifications of the G residues in the
upstream
telomeric repeat of this primer moderately
interfered with primer
extension. A similar degree of interference
caused by modification
of the upstream G residues was also observed in
assays performed
with another variant of oligo tel1 in which the T5
residue facing
A51 in the RNA was replaced with G (not shown). It
should also
be noted that modification of residue G5 in this
oligonucleotide
strongly interfered with the elongation of this
primer.
Inspection of the KMnO
4 footprint of oligo tel3
reveals that the interference caused by modification of residue T4 was
much
less substantial than that observed in the KMnO
4
footprint of
oligo tel1. A similar observation was made in a
KMnO
4 footprinting
assay of an additional variant of oligo
tel1 in which residue
T5 was deleted (not shown). Apparently, the
absence of T5 affected
the interactions of these primers with the
enzyme so that the
role of T4 in the reaction became less
significant.
(ii) Interference footprinting of complexes generated with primers
in which residues facing nucleotides 52 and 53 of the RNA subunit were
replaced.
It has been reported that nucleotides 52 and 53 in the
RNA template may also play a role in the alignment of
telomeric primers with the Tetrahymena
telomerase (19). It was therefore interesting to
determine whether replacement of the oligo tel1 residues G6 and G7,
which face these RNA nucleotides, with other bases would affect the
interference profiles of the substituted primers. We first used for
these assays oligo tel4, a variant of oligo tel1 in which G6 was
replaced with A. This substitution did not affect the efficiency of
extension of the unmodified oligo tel4 compared with that of oligo tel1
(Table 1). Figure 5A shows formic acid and KMnO4 interference assays performed with oligo tel4. It
can be seen that the interference profiles obtained in the assays of
this primer did not substantially differ from the profiles obtained in
the corresponding assays of oligo tel1. In particular, modification of
residue A6 caused a strong interference with the extension of oligo
tel4. In addition, modification of G7 in this oligonucleotide also
caused substantial interference with its elongation. Similar
interference profiles were obtained in assays of another
oligonucleotide in which G6 has been replaced with T and in assays of
two other oligonucleotides in which G7 has been replaced with either A
or T (not shown).
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FIG. 5.
Interference footprinting assays performed with oligo
tel1 variants containing substitutions of residues N6 and N7. Formic
acid (FA) and KMnO4 interference assays were carried out as
described in the legends to Fig. 3 and 4. (A) Formic acid (2.5%)
assays and 0.10 mM KMnO4 assays of oligo tel4. (B) Formic
acid (5%) assays and 0.10 mM KMnO4 assays of oligo tel5.
|
|
We have also studied the interactions of the telomerase
with oligo tel5, another variant of oligo tel1 in which two T residues
have been inserted at positions 6 and 7 of the primer. As Table
1
shows, the efficiency of extension of oligo tel5 was significantly
higher than that of oligo tel1. This result could be due to the
ability
of all four residues T4, T5, T6, and T7 in this oligonucleotide
to form
Watson-Crick hydrogen bonds with residues A50, A51, A52,
and A53 in the
telomerase RNA, unlike oligo tel1 (see Fig.
1).
Figure
5B
shows formic acid and KMnO
4 interference assays performed
with oligo tel5. It can be seen that, as in the case of oligo
tel1,
modification of residues 2 to 6 strongly interfered with
the
extension of oligo tel5. Modification of T7, G8, and G9 caused
a slight
interference compared with modification of other upstream
residues.
Thus, the ability of primer residues T6 and T7 to form
two additional
Watson-Crick hydrogen bonds with RNA residues A52
and A53 did not
substantially affect the interference profile
of this
primer.
Evidence that the presence or distribution of upstream
telomeric repeats did not substantially affect the
interference patterns.
The data presented so far indicated that
upstream telomeric repeats do not play a major role in the
elongation of primers that are properly aligned with the RNA template
region of the telomerase. Here we present footprinting
assays designed to further investigate the role of upstream
telomeric sequences in the elongation reaction.
First, we studied the elongation of primers consisting of
telomeric repeats exclusively. Attempts to extend a
23-nucleotide-long
primer containing four telomeric repeats
(and ending with GGG-3')
by a single [
32P]dGMP residue
revealed that the reaction was very strongly inhibited.
The inhibition
was probably due to formation of intramolecular
four-stranded DNA
structures (
59). Therefore, we used for these
assays a
17-base primer designated oligo tel6, which consisted
of three
telomeric repeats. It can be seen (Table
1) that the
efficiency of elongation of this primer by the telomerase
was
threefold lower than that of oligo tel1. This result could be
due
to the formation of unusual DNA structures other than four-stranded
DNA
by oligo tel6. Alternatively, it could result from the difference
in
length between the two oligonucleotides, oligo tel6 (17 residues)
being
shorter than oligo tel1 (21 residues). Figure
6A shows
formic
acid and KMnO
4 interference assays performed with
oligo tel6.
It can be seen that modifications of residues N2 to N6
caused
strong interference with the elongation of this primer. The
formic
acid data also showed a gradual decrease in the degree of
interference
resulting from modifications of residues G7, G8, and G9.
Overall,
these data and the data obtained in the assays performed with
KMnO
4 indicated that only moderate to slight interference
was
caused by modifications of G and T residues located upstream of
residue G6 in oligo tel6.
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FIG. 6.
Interference footprinting assays performed with primers
in which the number and distribution of telomeric repeats
have been varied. Formic acid (FA) and KMnO4 interference
assays were carried out as described in the legends to Fig. 3 and 4.
(A) Formic acid (2.5%) assays and 0.10 mM KMnO4 assays of
oligo tel6. (B) Formic acid (4%) assays and 0.12 mM KMnO4
assays of oligo tel7. (C) Formic acid (3%) assays and 0.15 mM
KMnO4 assays of oligo tel8. In these assays, bands
corresponding to residues 32 to 35 could not be resolved and hence were
not quantitated.
|
|
We next studied the elongation of oligo tel7, which lacks upstream
telomeric sequences. As Table
1 shows, the efficiency
of
elongation of oligo tel7 by a single G residue was about the
same as
that of oligo tel1. Figure
6B shows interference assays
carried out
with oligo tel7. It can be seen that strong interference
was only
observed when residues 2 to 6 were modified. Only slight
to moderate
interference was caused by modification of G, A, or
T residues located
further upstream in the nontelomeric
sequences.
We have also studied the interference patterns obtained with a
considerably longer oligonucleotide, oligo tel8, which contained
two
telomeric sequences at similar positions as in oligo tel1
and also contained a 14-base nontelomeric sequence at
the 5' end
(Table
1). Figure
6C shows formic acid and KMnO
4
interference
profiles obtained in assays of oligo tel8 and the
corresponding
histogram. It can be seen that modification of each of
the nucleotides
G2, G3, T4, T5, and G6 strongly interfered with the
elongation
of oligo tel8 by a single G residue. Modification of other
residues,
including G7 and nucleotides in the upstream
telomeric repeat,
only caused a moderate to a slight
interference with the reaction.
These data and the data reported in the
previous sections indicate
that the upstream telomeric
sequences do not play a major role
in the elongation of properly
aligned primers by a single dGMP
residue.
Evidence that the interference footprint is shifted relative to the
template during primer elongation by the telomerase.
We next performed formic acid and KMnO4 interference
footprinting analyses of the elongation of oligo tel9, which consisted of the oligo tel1 sequence and two additional residues, GT, at the 3'
terminus (Table 1). For this analysis, oligo tel9, in which the
residues were numbered 1', 2', 3', etc., was extended by a single
radioactively labeled dTMP residue, as indicated in Fig. 1B. Figure
7 (panel I) presents the footprints
obtained in these assays. In these gels, the bands corresponding to
residues T1' and G2' were not resolved well from the radioactively
labeled dTTP precursor and could not be analyzed. Panel II shows the
histogram of the relative interference values of the bands that were
identified in panel I. It can be seen that modification of the residues
included in the sequence extending between G3' and T7' caused
substantial interference with the extension of oligo tel9. However, the
interference that resulted from modification of T6' and T7' was not as
strong as that caused by modification of G3', G4', and G5'. Slight to moderate interference was caused by modification of some residues located further upstream.
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FIG. 7.
Interference footprinting performed with oligo tel9,
which ends with the sequence GGGGT-3' instead of GGG-3'. Formic acid
(FA) and KMnO4 interference assays were carried out as
described in the legends to Fig. 3 and 4 except that
[32P]dTTP was used for the primer extension reactions
instead of [32P]dGTP. The data presented are those
obtained in 5% formic acid assays and 0.15 mM KMnO4 assays
of oligo tel9.
|
|
It was interesting to compare these data with the data obtained in the
assays of oligo tel1. As Fig.
1 shows, oligo tel9 and
oligo tel1 were
aligned with the RNA template so that residues
1', 2', 3', etc., in
oligo tel9 were shifted downstream by 2 nucleotides
relative to
residues 1, 2, 3, etc., in oligo tel1. For example,
G5' in oligo tel9
corresponded to G3 in oligo tel1. We note that
modification of residues
G4' and G5' in oligo tel9 (Fig.
7) and
of the corresponding residues G2
and G3 in oligo tel1 (Fig.
3)
caused strong interference with the
extension of oligo tel9 and
oligo tel1, respectively. Also, the
interference patterns resulting
from modification of all the residues
upstream of G9' in oligo
tel9 were similar to the interference patterns
resulting from
modification of the corresponding residues upstream of
G7 in oligo
tel1. Notwithstanding these similarities, it is evident
that modification
of residue G6 in oligo tel1 caused strong
interference with the
extension of this oligonucleotide, while
modification of the corresponding
residue G8' in oligo tel9 caused a
considerably smaller interference
with its extension. This difference
is clearly illustrated in
Fig.
8, which
displays the ratios of the interference values of
corresponding
residues in oligo tel9 and oligo tel1. The ratio
G8'/G6 was
significantly higher than the other ratios displayed
in Fig.
8. The
ratios T6'/T4, T7'/T5, and G9'/G7 were also slightly
higher than the
other ratios. It should be noted that two other
independent assays
performed with both oligonucleotides gave similar
results. These data
indicated that the footprint of the six or
seven residues at the 3'
terminus was shifted downstream by 2
nucleotides in oligo tel9 relative
to the corresponding footprint
of oligo tel1. The significance of this
observation will be discussed
below.
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FIG. 8.
Ratios of the relative interference values at
corresponding positions along oligo tel9 and oligo tel1. The sequences
of the two oligonucleotides are shown at the bottom. The formic acid
(FA) and KMnO4 interference values observed at the
indicated positions in oligo tel9 were divided by the corresponding
values in oligo tel1.
|
|
| |
DISCUSSION |
We have presented in this paper an interference footprinting
analysis of interactions of the Tetrahymena
telomerase with single-stranded DNA primers in active
enzyme-primer elongation complexes. Specifically, this analysis
provided data on the degree to which chemical modifications of each
individual nucleotide in the primers interfered with their extension by
a single dGMP or dTMP residue. We surmise that the degree of
interference is a measure of the functional significance of the
interactions of each nucleotide in the primers with the telomerase RNP. It should be noted, however, that these
assays did not reveal whether the modifications interfered with the
binding of the primers to the enzyme or with the catalysis of
phosphodiester bond formation.
Our experiments have shown that the six 3'-terminal nucleotides of all
the primers that were used in this study strongly interacted with the
telomerase in the elongation complexes. Substantial
interactions were also observed with the seventh primer residue, but
these interactions varied in the various primers. In primers that ended with the sequence TGGG-3', the interactions detected by our
footprinting assays presumably included Watson-Crick hydrogen bonds
formed between these four nucleotides and the telomerase
RNA residues CCCA at positions 47 to 50 (see Fig. 1A). This inference
is based on previous studies of telomerase RNA mutants,
which indicated that the RNA residues CCC (47 to 49) served as
templating nucleotides and the A50 residue was needed for alignment of
the primers at the active site (19, 21). However, those
studies have also indicated that, in addition to the interactions with
the RNA template region, the same primer residues also interact with
the telomerase protein(s) or with other regions of the RNA.
This notion is now supported by our observation that modifications of
the three 3'-terminal G residues by DMS caused strong interference with
the extension of the primers, even though these modifications
(methylation of N7 in guanine residues) should not have affected the
ability of the primers to form Watson-Crick hydrogen bonds with the
templating nucleotides in the RNA. Interactions other than Watson-Crick
base-pairing with residue 4 in the primers were also demonstrated by
the footprinting assays of oligo tel2, in which the T4 residue has been
replaced with A (Fig. 4A). In line with these observations, kinetic
studies indicated that the binding of the E. aediculatus
telomerase to primers involves limited base-pairing (4 to
10 bp) with the RNA template region and substantial interactions with a
protein component of the enzyme (28).
We have also determined that the predominant interactions of the
telomerase with residues 5, 6, and 7, found upstream of the 3'-terminal TGGG in these primers, were not hydrogen bonds of the
Watson-Crick type (see Fig. 1). This conclusion was based on the
observation that similar extents of interference occurred in assays of
primers containing either T, G, or A residues at these positions, while
only T's could form Watson-Crick hydrogen bonds with the A residues at
the corresponding positions in the telomerase RNA.
Only weak interactions were observed between the telomerase
and residues located upstream of nucleotide 7 in the primers containing a 3' canonical Tetrahymena telomeric repeat.
Furthermore, these interactions were not substantially different in a
primer containing additional upstream telomeric repeats and
primers containing nontelomeric sequences at the
upstream positions. However, the interactions between the enzyme and
the upstream sequences were considerably enhanced in oligonucleotides
containing a mutated 3' telomeric repeat. The enhancement
was found to be most prominent in the assays performed with oligo tel2,
but some enhancement was also observed in the assays of oligo tel3 and
another related mutant oligo (see Fig. 4 and Results). These primers
were apparently impaired in the ability to align with the RNA template
region, and hence the overall efficiency of their extension was lower than the efficiency of extension of properly aligned primers (Table 1).
We suggest that the enhanced interactions with the upstream sequences
compensated for the impaired alignment of the 3'-terminal sequences.
These data appear to be compatible with previous studies of the
extension of primers which did not contain telomeric
repeats at the 3'-termini that could anneal with the RNA template
region before the first elongation cycle. The presence of upstream
telomeric sequences increased the efficiency of extension
of such primers by the Tetrahymena telomerase
and by two other telomerases (33, 45, 48).
Studies on the length dependence of the extension of entirely
nontelomeric primers also indicated that interactions of the telomerase with upstream sequences play a
significant role in their extension (55; for a
review, see reference 13).
Another significant observation made in the present study was the shift
in the footprint generated with oligo tel9 relative to the footprint
generated with oligo tel1 (Fig. 1, 3, 7, and 8). We suggest the scheme
shown in Fig. 9 to account for these data. According to this scheme, at stage I, a structural element in the
telomerase RNP, which is illustrated as a cylinder and designated the telomerase DNA-interacting surface (TDIS),
strongly interacts with the six 3'-terminal nucleotides (and to a
lesser extent with the seventh nucleotide) in the primers. During
elongation, TDIS moves along the primers and the RNA template region
and attains stage II. At this stage, TDIS is also associated with the
six or seven 3'-terminal nucleotides in the primers.
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FIG. 9.
Scheme for primer elongation by telomerase
based on the footprinting data. A structural element in the
telomerase, which is schematically illustrated as a
cylinder and designated the TDIS, strongly interacts with the six or
seven 3'-terminal nucleotides in the primers. As the primers are
elongated, TDIS moves in concert with their 3' termini along the
template region in the telomerase RNA (see the Discussion).
g and t are newly added oligonucleotides (Fig. 1).
|
|
Although our footprinting assays did not reveal which part of the
telomerase RNP interacts with the 3'-terminal nucleotides in the primers, it appears likely that the TERT subunit is involved in
these interactions and that TDIS is a part of TERT or contains a part
of TERT. The Tetrahymena TERT contains RT motifs, like the
TERTs of other organisms (11, 14). Thus, it belongs to the
RT subfamily of polymerases (12, 42). It is therefore interesting that in human immunodeficiency virus type 1 (HIV1) RT
template-primer elongation complexes, the seven 3'-terminal nucleotides
of the primers were found by footprinting assays to be protected
against hydroxyl radical cleavage (46). A more detailed
structural analysis revealed that a subdomain of this enzyme termed the
minor groove-binding track interacts with the minor groove of the
primer-template duplex along the second through the sixth base pairs
from the 3' primer terminus. It has been proposed that the minor
groove-binding track may slide along the minor groove as the nascent
strand is elongated (6). The similarity in the number and
positions of strongly interacting primer residues in the elongation
complexes of the telomerase and the HIV RT provides support
for the notion that the two enzymes are structurally related.
However, there are apparent differences in the topography of the
elongation complexes of the two enzymes. In the RT complexes, primer
residues N2 to N6 and all the residues located further upstream form a
duplex with the template. As Fig. 9 shows, of the corresponding N2 to
N6 primer residues in the stage I telomerase complexes,
which strongly interact with TDIS, only N2 to N5 can form duplexes with
the template. N6 is not included in the duplex region. Furthermore, in
some of the primers analyzed in the present study, N5 too is in a
single-stranded region. This situation changes as TDIS moves along the
template and attains stage II, in which all seven 3' residues in the
primers may form a duplex with the RNA. Clearly, in both stages I and
II, the primer residues located upstream of N7 do not form a duplex
with the template. Thus, unlike the minor groove-binding track in RT,
the interactions of TDIS with the primers may vary as the latter are
extended. These observations are consistent with the data of Wang et
al. (56), which also indicated that the
telomerase-primer interface may vary as the primers are
extended and form a longer duplex region with the template.
The scheme shown in Fig. 9 implies that during the elongation phase of
the primer extension process, two parts of the same telomerase molecule, the RNA template region and TDIS, move
relative to each other. We suggest that a similar movement may also
occur during the translocation phase, in which the
telomerase active site retreats from the 5' to the 3' end
of the template region before the onset of a new round of elongation
(13, 23). This suggestion implies that while the
Watson-Crick hydrogen bonds between the primer and the RNA template
region are disrupted during the translocation, the primers remain
anchored to the RNP through binding of the TDIS to some or all of the
six or seven 3'-terminal nucleotide residues. Thus, the translocation
mechanism suggested here may not require binding of a second site in
the telomerase to primer residues located upstream of
nucleotide N7. This type of movement would be analogous to the
coordinated retreat of the Escherichia coli RNA
polymerase and the transcription bubble that occurs at certain
transcription pause sites (36, 50). Clearly, further work is
required to test this hypothesis.
| |
ACKNOWLEDGMENTS |
Sima Benjamin and Nava Baran made equal contributions to the work
reported in this article.
This study was supported by grant 96-417 from the United
States-Israel Binational Science Foundation and by grant 980003-B from the Israel Cancer Association through the Ber-Lehmsdorf
Memorial Fund.
We thank Elizabeth H. Blackburn, David Gilley, and He Wang for advice
and helpful comments. We also thank James A. Borowiec for critical
reading of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biology, Technion-Israel Institute of Technology, Haifa 32000, Israel. Phone: 972-4-8293456. Fax: 972-4-8225153. E-mail:
manor{at}tx.technion.ac.il.
| |
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Molecular and Cellular Biology, June 2000, p. 4224-4237, Vol. 20, No. 12
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
