Department of Immunology and Oncology, Centro
Nacional de Biotecnología, Madrid E-28049,
Spain,1 and Department of Microbiology,
Boston University School of Medicine, Boston, Massachusetts
02118-25262
Received 2 November 2000/Returned for modification 11 December
2000/Accepted 23 February 2001
The major pathway in mammalian cells for repairing DNA
double-strand breaks (DSB) is via nonhomologous end joining. Five
components function in this pathway, of which three (Ku70, Ku80, and
the DNA-dependent protein kinase catalytic subunit [DNA-PKcs])
constitute a complex termed DNA-dependent protein kinase (DNA-PK).
Mammalian Ku proteins bind to DSB and recruit DNA-PKcs to the break.
Interestingly, besides their role in DSB repair, Ku proteins bind to
chromosome ends, or telomeres, protecting them from end-to-end fusions.
Here we show that DNA-PKcs
/ cells display an increased
frequency of spontaneous telomeric fusions and anaphase bridges.
However, DNA-PKcs deficiency does not result in significant changes in
telomere length or in deregulation of the G-strand overhang at the
telomeres. Although less severe, this phenotype is reminiscent of the
one recently described for Ku86-defective cells. Here we show that,
besides DNA repair, a role for DNA-PKcs is to protect telomeres, which
in turn are essential for chromosomal stability.
 |
INTRODUCTION |
One of the most lethal
lesions that can occur in a cell after ionizing irradiation is a
double-strand break (DSB), because it disrupts the integrity of the DNA
molecule. The importance of this lesion is evident by the existence of
evolutionarily conserved DNA repair systems that act on DSBs. Moreover,
DSBs are also generated under physiological conditions, such as during
transposition, meiosis, and recombination. It is important that these
endogenous breaks be resolved in order for cells to function properly.
Cells have evolved two fundamentally different pathways for repairing DSBs: homologous recombination (HR), which requires extensive regions
of homology, and DNA nonhomologous end joining (NHEJ). In contrast to
what has been described for Saccharomyces cerevisiae, the major pathway in mammalian cells is NHEJ. Five components function
in this pathway, of which three (Ku70, Ku80, and the DNA-dependent
protein kinase catalytic subunit [DNA-PKcs]) constitute a complex
termed DNA-dependent protein kinase (DNA-PK) (48). Xrcc4
and DNA ligase IV are the two additional proteins known to function in
the NHEJ pathway (19, 22, 37). The essential role of the
DNA-PK complex in NHEJ has been well documented in mice generated by HR
and carrying null mutations for any of the three subunits. The
phenotypes shared by these animals are defective DSB repair (dsbr), and
thus hypersensitivity to ionizing radiation, and an impaired V(D)J
recombination process (18, 25, 43, 44, 49, 52). However,
these animals present differential phenotypes, which provides
unequivocal evidence for additional roles for each component of the
DNA-PK complex separate from their function in NHEJ. In this
context, Ku-deficient mice grow poorly and senesce early (25, 36,
43, 51), a differential feature not observed in
DNA-PKcs-deficient mice (18, 49).
Telomeres are unique structures present at the end of eukaryotic
chromosomes and are composed of tandem DNA repeats and specific proteins, conferring properties that keep the ends from being detected
as DSBs by the cell (7). The fundamental difference between telomeres and DSBs is that telomeres are protected from end-to-end fusions, recombination, and unregulated nucleolytic degradation, whereas DSBs are subjected to such processing events in
order to promote repair of the break. In fact, when normal telomere
function is affected, either by loss of telomeric sequences or by
mutation of a protective telomere binding protein, i.e., TRF2,
end-to-end fusions occur (9, 14, 50). Telomeric sequences are lost during in vitro culture of primary cells and with increasing age in some adult tissues. Besides, an impairment of telomere function
due to a loss of telomeric sequences has been shown to limit the
proliferative capacity of cultured cells and to affect the life span of
the organism (4, 10).
Studies of yeast, where the major DNA repair pathway is HR
instead of NHEJ, show that Ku has an important role at the telomere. In
particular, yeast defective in either Ku subunit show a 60% loss of
telomeric repeats, loss of telomere clustering, loss of telomeric
silencing, and deregulation of the G-strand overhang (12, 13, 21,
35, 42). Furthermore, yeast Ku moves from the telomeres to the
DSB upon induction of damage, suggesting a link between DNA repair and
telomeres (38, 40). In mammals, Ku proteins have been
reported to bind to telomeric sequences (6, 31) and to
prevent end-to-end fusions (5, 32, 47); but in contrast to
what has been reported for yeast, Ku86 deficiency in mice does not
result in telomere shortening or in deregulation of the G-strand
overhang (47). It is likely that Ku protects mammalian
telomeres from fusions through its interaction with another telomeric
protein, TRF1 (32). DNA-PKcs is a member of the
phosphatidylinositol 3-kinase superfamily (27, 45), which includes, among others, the yeast Tel1 protein and human ATM, which
have been implicated in telomere metabolism (23, 39, 41).
Preliminary evidence suggesting a role for DNA-PKcs at the telomeres
came from studies conducted with severe combined immunodeficient (SCID)
mice carrying a leaky mutation in the DNA-PKcs locus. These
studies showed that SCID mouse telomeres were elongated compared to
those of wild-type mice and that SCID mouse cells had an increased
frequency of end-to-end fusions (2, 5,11, 15, 26, 33). In
addition, the Mre11-Rad50-NsbI dsbr complex is also present at the
mammalian telomere and interacts with telomeric protein TRF2
(53). Collectively, the recruitment of DSB DNA repair
proteins to the telomeres suggests that chromosome ends are binding
sites for dsbr proteins in mammals.
In the present study, the use of mice with a null mutation in the
DNA-PKcs gene (49) allowed us to demonstrate that
the absence of DNA-PKcs in mammals results in an increased frequency of
telomeric fusions and anaphase bridges, suggesting a protective role of
DNA-PKcs at the telomere independent to that reported for Ku proteins
(32, 47). Interestingly, DNA-PKcs deficiency, similar to
Ku86 deficiency, does not result in an alteration of telomere length or
the integrity of the G-strand overhang. In this context, the
contrasting results found for SCID mice that show elongated telomeres
compared to those of wild-type controls (26) (see below) might serve as
a means to discover important differences between these two
mouse models.
| |
MATERIALS AND METHODS |
Mice and cells.
DNA-PKcs null mice were described elsewhere
(49). Wild-type and DNA-PKcs/
mice or cells were derived from heterozygous crosses and, for all work,
littermate mice or cells were used. SCID mice used were BALB/cJHanHsd-Scid (Harlam, Barcelona, Spain), and the
corresponding wild-type mice in the same genetic background were
BALB/cOlaHsd (Harlam). Mice used for quantitative fluorescent in situ
hybridization (Q-FISH) and flow cytometry FISH (Flow-FISH)
studies were between 8 and 12 weeks old. Mouse embryonic fibroblasts
(MEFs) were prepared from day 13.5 embryos derived from heterozygous
crosses as described previously (9). First-passage MEFs
used in the different experiments corresponded to approximately two
population doublings (PDL 2). Mice or cells from the same litter are
indicated with the same letter.
Scoring of chromosomal abnormalities.
Between 80 and 100 (each) wild-type, DNA-PKcs+/, and
DNA-PKcs/ metaphases were scored for telomere
fusions, chromatid breaks, and chromosome fragments by superimposing
the telomere image on the DAPI (4',6'-diamidino-2-phenylindole)
chromosome image in the TFL-telo program. The following criteria were
applied: telomeric fusions, chromosomes fused by their telomeres
showing at least two overlapping telomeric signals; Robertson-like
fusions, chromosomes fused by their p arms (they may or may not show
telomeres at the fusion point; all the Robertson-like fusions found in
this study showed telomeres at the fusion point and were included in
the group of telomeric fusions); telomere associations, chromosomes with four distinct telomere signals but aligned less than one-half chromatid apart; breaks, gaps in a chromatid whose corresponding chromosome was identified; chromosome fragments, chromosome pieces (with two telomeres or less) whose corresponding chromosome was not
easily identified.
To score for anaphase bridges, primary MEF cultures were seeded on
microscope slides and stained with DAPI to visualize the DNA. At least
50 anaphases were scored for wild-type and
DNA-PKcs/ cultures, and the anaphase bridges
were counted.
Statistical analysis.
Statistical calculation was done using
Microsoft Excel. For statistical significance, Student's t
test values were calculated.
Telomere length analysis. (i) Q-FISH.
First-passage MEFs
were prepared for Q-FISH as described previously (29).
Q-FISH was carried out as described previously (29, 34,
47). To correct for lamp intensity and alignment, images from
fluorescent beads (Molecular Probes) were analyzed using the TFL-Telo
program. Telomere fluorescence values were extrapolated from the
telomere fluorescence of LY-R and LY-S lymphoma cell lines
(1) of known lengths of 80 and 10 kb (E. Samper et al.,
unpublished results). There was a linear correlation
(r2 = 0.999) between the fluorescence
intensities of the LY-R and -S telomeres with a slope of 38.6. The calibration-corrected telomere fluorescence intensity was
calculated as described previously (29).
Images were recorded using a COHU charge-coupled device camera on a
Leica Leitz DMRB fluorescence microscope. A Philips CS 100W-2 mercury
vapor lamp was used as the source. Images were captured using Leica
Q-FISH software at a 400-ms integration time in a linear-acquisition
mode to prevent oversaturation of fluorescence intensity.
TFL-Telo software (gift from P. M. Lansdorp, Vancouver, British
Columbia, Canada) was used to quantify the fluorescence intensity of
telomeres from at least 15 metaphases or fusions of each data point.
The images from littermate wild-type and
DNA-PKcs/ metaphases were captured on the
same day, in parallel, and blindly. All the images from the MEFs were
captured in a 3-day period after the hybridization.
(ii) Flow-FISH.
Fresh bone marrow (BM) cells, splenocytes,
and primary MEFs from littermate wild-type,
DNA-PKcs+/, and
DNA-PKcs/ mice, as well as splenocytes and BM
cells from SCID and control wild-type animals, were prepared as
described previously (9, 29, 30). Flow-FISH was performed
as described previously(46). To normalize Flow-FISH data
two mouse leukemia cell lines (LY-R and LY-S; described above) were
used as internal controls in each experiment. The telomere fluorescence
of at least 2,000 cells gated at the
G1-G0 cell cycle stage was
measured using a Coulter flow EPICS XL cytometer with SYSTEM 2 software.
(iii) TRF analysis.
Fresh BM cells from wild-type,
DNA-PKcs+/, and
DNA-PKcs/ littermate mice, as well as from
SCID mice and their corresponding wild types, were isolated as
described above, and telomere restriction fragment (TRF) analysis was
done as described by Blasco et al. (9).
G-strand overhang assay.
The G-strand assay was performed as
described previously (28) with minor modifications. Fresh
BM cells and MEFs (106) from several pairs
of wild-type mice and DNA-PKcs/ littermates
were included in restriction analysis grade agarose plugs in accordance
with instructions provided by the manufacturer (Bio-Rad). After
overnight digestion in LDS buffer (1% lithium dodecyl sulfate,
100 mM EDTA [pH 8.0], 10 mM Tris [pH 8.0]), the plugs were digested
with either 0, 40, or 100 U of mung bean nuclease (MBN) for 15 min.
Then the plugs were digested with MboI overnight and
subjected to pulsed-field gel electrophoresis as described previously (9). The sequential in-gel hybridizations in
native and denaturing conditions to visualize G-strand overhangs and telomeres, respectively, were carried out as described before (28). Quantification of the G-strand overhang radioactive
signals was carried out using a STORM 860 PhosphorImager (Molecular
Dynamics), using the software provided by the manufacturer. These
values were corrected by the TRF signal in denaturing gel conditions.
Telomerase assay.
S-100 extracts were prepared from
wild-type, DNA-PKcs+/, and
DNA-PKcs/ primary MEF cultures, and a
modified version of the TRAP assay was used to measure
telomerase activity (8). An internal control for PCR
efficiency was included (TRAPeze kit; Oncor).
| |
RESULTS |
DNA-PKcs is necessary to prevent telomere fusions and the formation
of anaphase bridges during mitosis.
Telomeres protect chromosome
ends from degradation, end-to-end fusions, and recombination
activities. To study the impact of DNA-PKcs deficiency on telomere
function, we analyzed the involvement of telomeres in the
chromosomal aberrations spontaneously arising in primary (passage
1) wild-type and DNA-PKcs/ MEFs derived from
heterozygous crosses. For this, we performed Q-FISH of metaphasic
nuclei with a fluorescent telomeric peptide nucleic acid probe
(47, 54) (see Materials and Methods for a description of
different aberrations) and then scored spontaneously arising chromosome
aberrations for 80 to 100 metaphases of each primary MEF culture. As
displayed in Table 1, no statistically significant differences between the frequency of chromosome breaks and
fragments detected in MEFs isolated from
DNA-PKcs/ cultures and that detected in
wild-type controls were found (0.026 and 0.032 breaks plus fragments
per metaphase, respectively; Student's t test,
P = 0.67475). Similarly, no significant difference in the frequency of telomeric associations (chromosomes with four distinct
telomere signals that are aligned less than one-half chromatid apart;
Fig. 1A) between genotypes was found
(0.015 and 0.012 telomeric associations per metaphase for
DNA-PKcs/ and wild-type MEFs, respectively)
(Table 1). Interestingly, DNA-PKcs/ MEFs
showed an elevated frequency of telomeric fusions (two chromosomes which are fused by at least one telomere; Fig. 1A) compared to wild-type controls; the average frequencies of fusions per metaphase were 0.065 and 0.017 for DNA-PKcs/ and
wild-type MEFs, respectively (Fig. 1; Table 1). All Robersonian-like fusions found (chromosomes fused by their p arms) showed telomeres at
the fusion point and were included in the group of telomeric fusions.
It is worth noting that the difference in telomeric fusions between
wild-type and DNA-PKcs/ cells is highly
significant (Student's t test, P = 0.00037174). The frequency of telomeric fusions found in the
DNA-PKcs/ primary MEFs was lower than that
previously reported for SCID mouse cells (0.165 telomeric fusions per
metaphase) which carry a leaky mutation in the DNA-PKcs gene
(5). We cannot rule out the possibility that the higher
chromosomal instability described for SCID cells is due to the higher
passage number of the SCID MEFs used by Bailey et al. (5)
compared with the passage 1 DNA-PKcs/ MEFs
used in this study.
View larger version (91K):
[in this window]
[in a new window]
|
FIG. 1.
Chromosomal instability in wild-type (WT) and
DNA-PKcs/ MEFs. (A) Cytogenetic alterations
detected in DNA-PKcs/ metaphases from primary
MEFs after hybridization with DAPI and a fluorescent Cy-3-labeled
telomeric peptide nucleic acid probe. For quantifications see Table 1.
Blue, chromosome DNA stained with DAPI; yellow and white dots,
TTAGGG repeats; yellow arrows, chromosomal abnormalities.
For definition of the different aberrations see Materials and Methods.
(B) Representative images of anaphase bridges in
DNA-PKcs/ cells. Blue, chromosome DNA stained
with DAPI. Notice the presence of DNA bridges in DNA-PKcs-deficient
cells even in late-anaphase and telophase stages.
|
|
Importantly, all chromosomal abnormalities present in
DNA-PKcs/ cells were also detected in primary
Ku86/ MEFs but at a significantly higher
frequency (47), suggesting additional roles for the Ku86
protein at the telomeres independent of the activity of the DNA-PK complex.
It is important to note that Q-FISH analysis allowed us to determine
that all telomeric fusions present in
DNA-PKcs/ cells contained intact telomeres at
the fusion point with an average length of 64.4 ± 9.39 kb,
suggesting that these fusions did not originate from a loss of
telomeric sequences. A similar phenotype has been previously described
for Ku86 deficiency (47).
Finally, loss of telomere function has been proposed to trigger
breakage-fusion-bridge cycles (3, 16) through the
formation of telomeric fusions and the occurrence of anaphase bridges
during mitosis. Both types of chromosomal aberrations occur in tumors and are thought to be important for their clonal evolution and progression (20). In agreement with a role for DNA-PKcs in
telomere function and chromosomal stability, we found that
DNA-PKcs/ MEFs showed a significantly higher
frequency of anaphase bridges than control cells (0.16 and 0.70 anaphase bridges per anaphase scored for wild-type and
DNA-PKcs/ MEFs, respectively; 50 anaphases of
each cell type were scored) (Fig. 1B shows examples). This difference
is highly significant, as indicated by the Student t test
value (P = 0.0014). Some anaphase bridges were still
present at telophase in the DNA-PKcs/ cells
(Fig. 1B shows examples). Altogether, these results strongly suggest a
role for DNA-PKcs in protecting chromosome ends and thus a role in
genomic stability.
Normal length of TTAGGG repeats in DNA-PKcs-deficient
cells.
To determine if the protective role of DNA-PKcs at the
telomere is mediated by the length of TTAGGG repeats,
quantification of telomere length was carried out for littermate
wild-type and DNA-PKcs/ mice or embryos
derived from heterozygous crosses. It is essential to compare
littermate mice since mouse telomeres show individual variability
(54). Q-FISH analysis of MEFs from wild-type and DNA-PKcs/ littermate mice revealed
that DNA-PKcs/ cells had a telomere length
similar to that of the wild type (Table 1). The average telomere
lengths were 33.95 ± 0.2 and 35.0 ± 0.2 kb for MEFs from
DNA-PKcs/ (average of B6, C2, and C9) and
wild-type (average of B5, C5, and C3) littermate mice, respectively
(Fig. 2). The Q-FISH data on MEFs were
confirmed by using a different technique to measure telomere
fluorescence based on flow cytometry (Flow-FISH; described in Materials
and Methods) (Table 2). In this case,
average telomere fluorescence levels expressed in arbitrary units were
2.58 ± 0.1, 2.72 ± 0.2, and 2.71 ± 0.1 for
DNA-PKcs/ (average of A1, B4, B6, C2, and
C9), DNA-PKcs/+ (average of A2 and B3), and
wild-type (average of B5, C3, and C5) MEFs, respectively. Histograms
showing the frequency of a given telomere fluorescence in MEFs from
littermate wild-type (B5, C5, and C3) and
DNA-PKcs/ (B6, C2, and C9) mice are presented
in Fig. 2. These histograms confirmed that the mean telomere
fluorescence levels in DNA-PKcs/ and
wild-type MEFs are similar and furthermore showed that the levels of
heterogeneity of telomeric lengths in both genotypes are similar (Fig.
2).
View larger version (23K):
[in this window]
[in a new window]
|
FIG. 2.
Telomere fluorescence distribution in wild-type (wt),
DNA-PKcs+/, and DNA-PKcs/ MEFs. Shown is
the telomere length distribution of at least 7,100 telomeres in primary
MEFs from three different littermate wt (B5, C5, and C3) and
DNA-PKcs/ (B6, C2, and C9) mice. The histograms depict
similar telomeres in DNA-PKcs/ and wt cells. One
telomere fluorescence unit corresponds to 1 kb of TTAGGG
repeats (see Tables 1 and 2 for telomere length values).
|
|
Flow-FISH studies on fresh splenocytes and BM cells derived from
wild-type, DNA-PKcs+/, and
DNA-PKcs/ littermate mice (8 to 12 weeks old)
also indicated that DNA-PKcs/ telomeres were
similar in length to those of wild-type littermates (Table
3), in agreement with the Q-FISH and
Flow-FISH data for MEFs. These results were reproducible in at least
six independent litters (Table 3).
View this table:
[in this window]
[in a new window]
|
TABLE 3.
Measurement by Flow-FISH of telomere length in
splenocytes and BM cells obtained from DNA-PKcs+/+,
DNA-PKcs+/, and DNA-PKcs/ mice
|
|
Finally, telomere length was also evaluated by Southern blotting, as an
alternative technique to measure telomere length not based on
fluorescence. Primary BM cells from three wild-type, three
DNA-PKcs+/, and four
DNA-PKcs/ mice were subjected to TRF analysis
as described in Materials and Methods. As shown in Fig.
3, TRF analysis also showed similar telomere lengths in littermate mouse wild-type and
DNA-PKcs/ cells.
View larger version (71K):
[in this window]
[in a new window]
|
FIG. 3.
TRF analysis of wild-type, DNA-PKcs+/, and
DNA-PKcs/ primary MEFs. Wild-type (+/+; DA45, DA46, and
DA60), DNA-PKcs+/ (+/ ; DA50, DA51, and DA59), and
DNA-PKcs/ (/; DA47, DA48, DA52, and DA58)
littermate mice were studied. Notice that TRF signals are similar in
DNA-PKcs/, DNA-PKcs+/, and wild-type BM
cells (see also Table 3 and Fig. 5 for other analyses of the same BM
cells). Three litters were analyzed.
|
|
Altogether, these data demonstrate that a
DNA-PKcs/ deficiency in mammals does not
result in significant telomere length alterations.
A spontaneous mouse mutation that also affects the DNA-PKcs locus but
that produces a leaky phenotype is the mutation resulting in SCID mice
(2, 11, 15, 33). Curiously, a previous report showed elongated telomeres in SCID mice compared to those in wild-type controls (26), which is in contrast to the
normal-telomere-length phenotype displayed by
DNA-PKcs/ animals in this study. To rule out
the possibility that possible technical differences between
laboratories were the reason for this discrepancy, we measured telomere
length for wild-type and SCID mice using the same methods used to
measure telomere length in DNA-PKcs-deficient cells. First, we
performed Flow-FISH of fresh splenocytes and BM cells isolated from
five SCID and five wild-type mice in the same genetic background (see
Materials and Methods). In agreement with results previously reported
by Hande et al. (26), we found that SCID mouse telomeres
were elongated compared with those of wild-type mice (Table
4; Fig.
4A). Average levels of telomere
fluorescence for freshly isolated splenocytes from five different
wild-type and SCID mice were 3.13 ± 0.33 and 5.27 ± 0.53, respectively. This difference was highly significant (Student's
t test, P = 1.2 × 105). Similarly, average levels of telomere
fluorescence for fresh BM cells from five different wild-type and SCID
mice were 3.24 ± 0.72 and 4.64 ± 1.24, respectively. This
difference was also significant (Student's t test,
P = 0.0170). Furthermore, TRF analysis of five
different wild-type and SCID mice also showed dramatically elongated
telomeres in the SCID mice compared with the wild types (Fig. 4B). The
elongated-telomere phenotype of SCID mice could also explain the
difference in the frequency of telomeric fusions between SCID and
DNA-PKcs/ mice (see above). These results
indicate fundamental differences between these two mouse models, at
least in terms of telomere function. These differences can be explained
if SCID mice carry other mutations besides the DNA-PKcs leaky
mutation. Alternatively, the fact that SCID mice are not
completely kinase null for the DNA-PKcs gene, and indeed express
a different truncated form of the DNA-PKcs gene, could differentially
affect telomere length and/or function.
View this table:
[in this window]
[in a new window]
|
TABLE 4.
Measurement by Flow-FISH of telomere length in
splenocytes and BM cells obtained from SCID and wild-type mice
|
|
View larger version (42K):
[in this window]
[in a new window]
|
FIG. 4.
Telomere length analysis of fresh BM cells and
splenocytes from SCID and wild-type (wt) mice. (A) Flow-FISH. Telomere
fluorescence (in arbitrary units [a.u.]) of splenocytes and BM cells
as measured by flow cytometry for five different SCID and wt mice is
shown. The average telomere lengths and standard deviations are
indicated. The statistical significance of the difference in telomere
fluorescence between SCID and wt mice is indicated by the Student's
t test numbers (P). (B) TRF analysis. BM
from wt and SCID mice in the same genetic background (see Materials and
Methods) was used for TRF analysis. Notice that TRFs were dramatically
elongated in SCID mice compared with wt controls.
|
|
Normal-length telomeric G-strand overhangs in
DNA-PKcs/ cells.
G-strand overhangs are regions of
G-rich single-stranded telomeric DNA that protrude in the 3'direction
from the double-stranded telomere. These single-stranded G-rich regions
have been recently involved in the formation of a special structure at
the chromosome end named the T loop, which has been proposed to protect
the ends from recombination and DNA repair activities
(24). Hence, examination of telomeric G-strand overhangs
in DNA-PKcs null cells was crucial to gain more insight into the
abnormal frequency of telomeric fusions and anaphase bridges detected
in these cells. To study the telomeric G-strand overhangs, we carried
out TRF analysis with a (CCCTAA)4
probe as described previously (28) using nondenaturing pulsed-field agarose gels (see Materials and Methods). Detection of a
signal with the (CCCTAA)4 probe
hybridized to native DNA samples indicates the presence of the G-strand
overhang. Freshly isolated BM cells, as well as primary MEFs from
different littermate wild-type, DNA-PKcs+/, and
DNA-PKcs/ mice showed G-strand-specific
signals that were similar in size and intensity in all genotypes (Fig.
5). Table
5 shows the quantification of the
G-strand signals; the wild-type values were normalized to 100 in each
litter. The average G-strand signal for
DNA-PKcs/ MEFs or BM cells was 81.8 ± 21.7% that for the wild types; this difference is not statistically
significant (Student's t test, P = 0.135).
To show that the probe specifically recognized the single-stranded
telomeric tail, treatment with MBN, which specifically degrades
single-stranded DNA and RNA overhangs, was performed. As expected, the
G-strand signal decreased in all genotypes upon treatment, as shown in
Fig. 5 ("native gel"). As a control, the same gel was denatured and
rehybridized with the (CCCTAA)4 probe, which highlighted the TRFs (Fig. 5; "denaturing gel"), again
showing no difference in TRF lengths between wild-type,
DNA-PKcs+/, and
DNA-PKcs/ phenotypes.
View larger version (254K):
[in this window]
[in a new window]
|
FIG. 5.
Normal G-strand overhang in
Ku86/-deficient primary cells. G-strand overhangs in
fresh BM cells or primary MEFs, as indicated, from littermate wild-type
and DNA-PKcs/ mice were visualized in native gel after
hybridization with a (CCCTAA)4 probe (see
Materials and Methods). Notice that upon treatment with two different
doses of MBN (40 and 100 U) the G-strand-specific signal decreases. As
a control, the same gel was denatured and reprobed with the
(CCCTAA)4 probe to visualize telomeres. DA40 and
DA39 are littermate wild-type and DNA-PKcs/ mice,
respectively. B3, B4, B5, and B6 are primary MEF cultures from
littermates, as are C2, C3, C5, and C9. See Table 5 for
quantification of G-strand-specific signals. HMW, high molecular
weight.
|
|
Collectively, these results show that DNA-PKcs deficiency in mammals
does not result in the loss or shortening of the G-strand overhang at
the telomeres. A similar result has been reported for the Ku86
deficiency, another member of the NHEJ pathway and component of the
DNA-PK complex (47).
DNA-PKcs activity does not regulate telomerase activity.
To
investigate if the protein kinase activity of the DNA-PKcs subunit
could have a regulatory role in telomerase activity (i.e., by
phosphorylating the catalytic subunit of telomerase Tert), we
quantified telomerase activity in three wild-type, one DNA-PKcs+/, and four
DNA-PKcs/ primary MEF cultures (passage 1)
(see Materials and Methods). No significant difference in telomerase
activity between wild-type and DNA-PKcs/
littermates was detected (Fig. 6). This
result indicates that lack of DNA-PK activity does not impact
telomerase activity in mice and in turn is in agreement with the normal
telomere length detected in DNA-PKcs-deficient cells.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 6.
Telomerase activity in wild-type and
DNA-PKcs/ MEFs. S-100 extracts were prepared from
wild-type (C3, C5, and B5), DNA-PKcs+/ (B3), and
DNA-PKcs/ (C2, C9, B4, and B6) MEFs and assayed for
telomerase activity. Extracts were pretreated (+) or not () with
RNase. The protein concentrations used are indicated. Arrow,
internal control (IC) for PCR efficiency. The same letter indicates
littermate embryos.
|
|
| |
DISCUSSION |
The essential role of the DNA-PK complex in dsbr and V(D)J
recombination in vertebrates is universally recognized. Biochemical analyses established that DNA-PK is a Ser/Thr kinase complex that must
be bound to DNA in order to be activated. DNA-PK is composed of three
subunits, a DNA end-binding component, which is a dimer of Ku70 and
Ku86, and a large catalytic subunit of 460 kDa referred to as DNA-PKcs.
Here we show that DNA-PKcs deficiency in mice results in increased
end-to-end telomeric fusions and in a higher frequency of anaphase
bridges in cells that otherwise show normal-length TTAGGG
repeats at the telomeres and at the G-strand overhang. These
results suggest a protective role for DNA-PKcs at the mammalian telomere that, in addition, is independent from the one conferred by
telomeric repeats per se or by the length of the G-strand overhang. Telomeric fusions and anaphase bridges lead to breakage-fusion-bridge events, which in turn are important features found in human cancers (20).
An increase in the frequency of telomeric fusions has been
recently reported for Ku86-deficient mice (47), suggesting
that both Ku and DNA-PKcs have a role at the telomere. However, in contrast to DNA-PKcs-deficient cells, Ku86/
cells show a slightly elongated telomere phenotype (47).
These results suggest an additional role for the Ku86 protein at the telomere independent of that for the DNA-PK catalytic activity per se.
This differential outcome between DNA-PKcs and Ku86 is not surprising
if we consider that a mutation in Ku86 not only inactivates Ku86 per se
but also impairs DNA-PK activity. This is also in agreement with
the complex phenotype observed in Ku86/ mice
compared to DNA-PKcs/ animals (18, 25,
43, 49, 51). Although Ku86 and DNA-PKcs gene products belong to
the same enzymatic complex, several studies have demonstrated the
differential role of these proteins in DNA repair and V(D)J
recombination (18, 25, 43, 44, 49).
Our finding of increased telomeric fusions in DNA-PKcs null cells has
been confirmed in recent experiments using SCID mice carrying a
spontaneous rodent DNA-PKcs gene mutation (5). In contrast to what we found for DNA-PKcs deficiency, however, Hande et
al. (26) reported an elongated-telomere phenotype in the SCID mice compared to wild-type controls. Using Flow-FISH and TRF
techniques, we have been able to confirm that SCID but not DNA-PKcs/ mice show elongated telomeres
compared with the corresponding wild-type controls. These results
indicate fundamental differences between
DNA-PKcs/ and SCID mice, at least in terms of
telomere function. These differences could be attributed (i) to the
occurrence of still-to-be-defined additional mutations in the SCID
strain which may affect telomere length, (ii) to the fact that SCID
does not represent a null mutation for the DNA-PKcs gene and to
potential residual kinase activity, and (iii) to the different types of
truncation in the DNA-PKcs gene product in SCID and
DNA-PKcs/ cells that might impact the
recruitment of other components necessary for telomere length
regulation (2, 11, 15).
Collectively, these results indicate that the DNA-PK complex has a role
in protecting telomeres from fusions. Interestingly, the DNA-PK complex
is involved in dsbr in mammals by NHEJ; however, in combination with
telomeric proteins, it might be involved in masking chromosome ends to
prevent them from being recognized as DSBs. In fact, the telomere
fusions detected in DNA-PKcs-deficient cells might represent NHEJ
events. In this regard, mutations in DNA repair proteins do not abolish
the capability of the cells to carry out NHEJ on broken ends (16,
36).
The end-to-end fusion phenotype has been previously recreated in cells
that lack telomerase activity and that undergo progressive telomere
shortening with increasing cell divisions (9). Likewise, cells expressing a dominant-negative mutation of the TRF2 gene had an
end-to-end fusion phenotype with normal telomere length but with loss
of G-strand overhang (24, 50). Since the protective functions of DNA-PKcs and Ku86 at the telomere are independent of the
length of TTAGGG repeats and of the integrity of the
telomeric G-strand overhang, this suggests that the DNA-PK complex acts at the telomere in a fundamentally different way than telomerase (8) or TRF2 (24, 50). However, it is still
possible that DNA-PKcs and Ku act similarly to TRF2 but that their
functions are more redundant, giving rise to a less severe phenotype.
There are a number of ways, not necessarily mutually exclusive, that
DNA-PK might function in telomere protection. One is that the protein
kinase activity of DNA-PKcs is employed to regulate the binding
activities of other telomeric components. Alternatively, in light of
the large size of DNA-PKcs, it is tempting to speculate that it might
have a role as a scaffolding protein, recruiting several other factors
to the telomere. These results warrant future studies involving the
evaluation of a putative synergistic effect between DNA-PK components
and telomere components as means to shed more light on the biology of telomeres.
E.S. and F.G. were supported by the Government of Madrid (CAM).
G.E.T. is a scholar of the Leukemia and Lymphoma Society. The G.E.T.
laboratory was supported by National Institutes of Health CA76409,
American Cancer Society IN97T, and the Aids for Cancer Research
Foundation. The M.A.B. laboratory was funded by the SWISS BRIDGE award,
2000, by the Ministry of Science and Technology (PM97-0133), Spain, by
CAM 08.1/0030/98, by the European Union (EURATOM/991/0201,
FIGH-CT-1999-00002, FIS5-1999-00055), and by the Department of
Immunology and Oncology (DIO). The DIO is funded by the Spanish Council
for Scientific Research and by Pharmacia Corporation.
F. A. Goytisolo and E. Samper contributed equally to this work.
| 1.
|
Alexander, P., and Z. B. Mikulski.
1961.
Mouse lymphoma cells with different radiosensitivities.
Nature
192:572-573.
|
| 2.
|
Araki, R.,
A. Fujimori,
K. Hamatani,
K. Mita,
T. Saito,
M. Mori,
R. Fukumura,
M. Morimyo,
M. Muto,
M. Itoh,
K. Tatsumi, and M. Abe.
1997.
Nonsense mutation at Tyr-4046 in the DNA-dependent protein kinase catalytic subunit of severe combined immune deficiency mice.
Proc. Natl. Acad. Sci. USA
94:2438-2443[Abstract/Free Full Text].
|
| 3.
|
Artandi, S. E.,
S. Chang,
S.-L. Lee,
S. Alson,
G. J. Gottlieb,
L. Chin, and R. DePinho.
2000.
Telomere dysfunction promotes nonreciprocal translocations and epithelial cancers in mice.
Nature
406:641-645[CrossRef][Medline].
|
| 4.
|
Autexier, C., and C. W. Greider.
1996.
Telomerase and cancer: revisiting the telomere hypothesis.
Trends Biochem.
21:387-391[CrossRef][Medline].
|
| 5.
|
Bailey, S. M.,
J. Meyne,
D. J. Chen,
A. Kurimasa,
G. C. Li,
B. E. Lehnert, and E. H. Goodwin.
1999.
DNA double-strand break repair proteins are required to cap the ends of mammalian chromosomes.
Proc. Natl. Acad. Sci. USA
96:14899-14904[Abstract/Free Full Text].
|
| 6.
|
Bianchi, A., and T. de Lange.
1999.
Ku binds telomeric DNA in vitro.
J. Biol. Chem.
274:21223-21227[Abstract/Free Full Text].
|
| 7.
|
Blackburn, E. H.
1991.
Structure and function of telomeres.
Nature
350:569-573[CrossRef][Medline].
|
| 8.
|
Blasco, M. A.,
M. Rizen,
C. W. Greider, and D. Hanahan.
1996.
Differential regulation of telomerase activity and telomerase RNA during multi-stage tumorigenesis.
Nat. Genet.
12:200-204[CrossRef][Medline].
|
| 9.
|
Blasco, M. A.,
H.-W. Lee,
P. Hande,
E. Samper,
P. Lansdorp,
R. DePinho, and C. W. Greider.
1997.
Telomere shortening and tumor formation by mouse cells lacking telomerase RNA.
Cell
91:25-34[CrossRef][Medline].
|
| 10.
|
Blasco, M. A.,
S. M. Gasser, and J. Lingner.
1999.
Telomeres and telomerase.
Genes Dev.
13:2353-2359[Free Full Text].
|
| 11.
|
Blunt, T.,
D. Gell,
M. Fox,
G. E. Taccioli,
A. R. Lehmann,
S. P. Jackson, and P. A. Jeggo.
1996.
Identification of a non-sense mutation in the carboxyl terminal region of DNA-dependent protein kinase catalytic subunit in the SCID mouse.
Proc. Natl. Acad. Sci. USA
93:10285-10290[Abstract/Free Full Text].
|
| 12.
|
Boulton, S. J., and S. P. Jackson.
1996.
Identification of a Saccharomyces cerevisiae Ku80 homolog: roles in DNA double strand break rejoining and in telomeric maintenance.
Nucleic Acids Res.
24:4639-4648[Abstract/Free Full Text].
|
| 13.
|
Boulton, S. J., and S. P. Jackson.
1998.
Components of the Ku-dependent non-homologous end-joining pathway are involved in telomeric length maintenance and telomeric silencing.
EMBO J.
17:1819-1828[CrossRef][Medline].
|
| 14.
|
Counter, C. M.,
A. A. Avilion,
C. E. LeFeuvre,
N. G. Stewart,
C. W. Greider,
C. B. Harley, and S. Bacchetti.
1992.
Telomere shortening associated with chromosome instability is arrested in immortal cells which express telomerase activity.
EMBO J.
11:1921-1929[Medline].
|
| 15.
|
Danska, J. S.,
D. P. Holland,
S. Mariathasa,
K. M. Williams, and C. J. Guidos.
1996.
Biochemical and genetic defects in the DNA-dependent protein kinase in murine scid lymphocytes.
Mol. Cell. Biol.
16:5507-5517[Abstract].
|
| 16.
|
de Lange, T.
1995.
Telomeres, p. 265-293.
Cold Spring Harbor Press, Cold Spring Harbor, N.Y.
|
| 17.
|
DiBiase, S. J.,
Z. C. Zeng,
R. Chen,
T. Hyslop,
W. J. Curran, Jr., and G. Iliakis.
2000.
DNA-dependent protein kinase stimulates an independently active, nonhomologous, end-joining apparatus.
Cancer Res.
60:1245-1253[Abstract/Free Full Text].
|
| 18.
|
Gao, Y.,
J. Chaudhuri,
C. Zhu,
L. Davidson,
D. T. Weaver, and F. W. Alt.
1998.
A targeted DNA-PKcs-null mutation reveals DNA-PK-independent functions for Ku in V(D)J recombination.
Immunity
9:367-376[CrossRef][Medline].
|
| 19.
|
Gao, Y.,
D. O. Ferguson,
W. Xie,
J. P. Manis,
J. Sekiguchi,
K. M. Frank,
J. Chaudhuri,
J. Horner,
R. A. DePinho, and F. W. Alt.
2000.
Interplay of p53 and DNA-repair protein XRCC4 in tumorigenesis, genomic stability and development.
Nature
404:897-900[CrossRef][Medline].
|
| 20.
|
Gisselsson, D.,
L. Pettersson,
M. Hoglund,
M. Heidenblad,
L. Gorunova,
J. Wiegant,
F. Mertens,
P. Dal Cin,
F. Mitelman, and N. Mandahl.
2000.
Chromosomal breakage-fusion-bridge events cause genetic intratumor heterogeneity.
Proc. Natl. Acad. Sci. USA
97:5357-5362[Abstract/Free Full Text].
|
| 21.
|
Gravel, S.,
M. Larrivee,
P. Labrecque, and R. J. Wellinger.
1998.
Yeast Ku as a regulator of chromosomal DNA end structure.
Science
280:741-744[Abstract/Free Full Text].
|
| 22.
|
Grawunder, U.,
M. Wilm,
X. Wu,
P. Kulesza,
T. E. Wilson,
M. Mann, and M. Lieber.
1997.
Activity of DNA ligase IV stimulated by complex formation with XRCC4 protein in mammals.
Nature
388:492-495[CrossRef][Medline].
|
| 23.
|
Greenwall, P. W.,
S. L. Kronmal,
S. E. Porter,
J. Gassenhuber,
B. Obermaier, and T. D. Petes.
1995.
Tel1, a gene involved in controlling telomere length in S. cerevisiae, is homologous to the human ataxia telangiectasia gene.
Cell
82:823-829[CrossRef][Medline].
|
| 24.
|
Griffith, J. D.,
L. Comeau,
S. Rosenfield,
R. M. Stansel,
A. Bianchi,
H. Moss, and T. de Lange.
1999.
Mammalian telomeres end in a large duplex loop.
Cell
97:503-514[CrossRef][Medline].
|
| 25.
|
Gu, Y. S.,
S. F. Jin,
Y. J. Gao,
D. T. Weaver, and F. W. Alt.
1997.
Ku70 deficient embryonic stem cells have increased ionizing radiosensitivity, defective DNA end binding activity, and inability to support V(D)J recombination.
Proc. Natl. Acad. Sci. USA
94:8076-8081[Abstract/Free Full Text].
|
| 26.
|
Hande, P.,
P. Slijepcevic,
A. Silver,
S. Bouffler,
P. van Buul,
P. Bryant, and P. Lansdorp.
1999.
Elongated telomeres in scid mice.
Genomics
56:221-223[CrossRef][Medline].
|
| 27.
|
Hartley, K. O.,
D. Gell,
G. C. M. Smith,
H. Zhang,
N. Divecha,
M. A. Conolley,
A. Admon,
S. P. Lees-Miller,
C. W. Anderson, and S. P. Jackson.
1995.
DNA-dependent protein kinase catalytic subunit: a relative of phosphatidylinositol 3-kinase and the ataxia telangiectasia gene product.
Cell
82:849-856[CrossRef][Medline].
|
| 28.
|
Hemann, M. T., and C. W. Greider.
1999.
G-strand overhangs on telomeres in telomerase deficient mouse cells.
Nucleic Acids Res.
27:3964-3969[Abstract/Free Full Text].
|
| 29.
|
Herrera, E.,
E. Samper,
J. Martín-Caballero,
J. M. Flores,
H.-W. Lee, and M. A. Blasco.
1999.
Disease states associated to telomerase deficiency appear earlier in mice with short telomeres.
EMBO J.
18:2950-2960[CrossRef][Medline].
|
| 30.
|
Herrera, E.,
C. Martinez, and M. A. Blasco.
2000.
Impaired germinal center formation in telomerase-deficient mice.
EMBO J.
19:472-481[CrossRef][Medline].
|
| 31.
|
Hsu, H.-L.,
D. Gilley,
E. Backburn, and D. J. Chen.
1999.
Ku is associated with the telomere in mammals.
Proc. Natl. Acad. Sci. USA
96:12454-12458[Abstract/Free Full Text].
|
| 32.
|
Hsu, H.-L.,
D. Gilley,
S. A. Galande,
M. P. Hande,
B. Allen,
S.-H. Kim,
G. C. Li,
J. Campisi,
T. Kowhi-Shigematsu, and D. J. Chen.
2000.
Ku acts in a unique way at the mammalian telomere to prevent end joining.
Genes Dev.
14:2807-2812[Abstract/Free Full Text].
|
| 33.
|
Kirchgessner, C. U.,
C. K. Patil,
J. W. Evans,
C. A. Cuomo,
L. M. Fried,
T. Carter,
M. A. Oettinger, and J. M. Brown.
1995.
DNA-dependent kinase (p350) as a candidate gene for the murine SCID defect.
Science
267:1178-1183[Abstract/Free Full Text].
|
| 34.
|
Lansdorp, P. M.,
N. P. Verwoerd,
F. M. van de Rijke,
V. Dragowska,
M.-T. Little,
R. W. Dirks,
A. K. Raap, and H. J. Tanke.
1996.
Heterogeneity in telomere length of human chromosomes.
Hum. Mol. Genet.
5:685-691[Abstract/Free Full Text].
|
| 35.
|
Laroche, T.,
S. G. Martin,
M. Gotta,
H. C. Gorham,
F. E. Pryde,
E. J. Louis, and S. M. Gasser.
1998.
Mutation of yeast Ku genes disrupts the subnuclear organization of telomeres.
Curr. Biol.
8:653-656[CrossRef][Medline].
|
| 36.
|
Li, G. C.,
H. H. Ouyang,
X. L. Li,
H. Nagasawa,
J. B. Little,
D. J. Chen,
C. C. Ling,
Z. Fuks, and C. Cordón-Cardó.
1998.
ku70: a candidate tumor suppressor gene for murine T cell lymphoma.
Mol. Cell
2:1-8[CrossRef][Medline].
|
| 37.
|
Li, Z.,
T. Otevrel,
Y. Gao,
H.-L. Cheng,
B. Seed,
T. D. Stamato,
G. E. Taccioli, and F. W. Alt.
1995.
The XRCC4 gene encodes a novel protein involved in DNA double-strand break repair and V(D)J recombination.
Cell
83:1079-1089[CrossRef][Medline].
|
| 38.
|
Martin, S. G.,
T. Laroche,
N. Suka,
M. Grunstein, and S. M. Gasser.
1999.
Relocalization of telomeric Ku and SIR proteins in response to DNA double-strand breaks.
Cell
97:621-633[CrossRef][Medline].
|
| 39.
|
Metcalfe, J. A.,
J. Parkhill,
L. Campbell,
M. Stacey,
P. Biggs,
P. J. Byrd, and A. M. Taylor.
1996.
Accelerated telomere shortening in ataxia telangiectasia.
Nat. Genet.
13:350-353[CrossRef][Medline].
|
| 40.
|
Mills, K. D.,
D. A. Sinclair, and L. Guarente.
1999.
MEC1-dependent redistribution of the Sir3 silencing protein from telomeres to DNA double-strand breaks.
Cell
97:609-620[CrossRef][Medline].
|
| 41.
|
Morrow, D. M.,
D. A. Tagle,
Y. Shiloh,
F. S. Collins, and P. Hieter.
1995.
Tel 1, an S. cerevisiae homolog of the human gene mutatedin ataxia telangiectasia, is functionally related to the yeast checkpoint gene MEC1.
Cell
82:831-840[CrossRef][Medline].
|
| 42.
|
Nugent, C. I.,
G. Bosco,
L. O. Ross,
S. K. Evans,
A. P. Salinger,
J. K. Moore,
J. E. Haber, and V. Lundblad.
1998.
Telomere maintenance is dependent on activities required for end repair of double-strand breaks.
Curr. Biol.
8:657-660[CrossRef][Medline].
|
| 43.
|
Nussenzweig, A.,
C. H. Chen,
V. D. Soares,
M. Sanchez,
M. C. Sokol,
M. C. Nussenzweig, and G. C. Li.
1996.
Requirement for Ku80 in growth and immunoglobulin V(D)J recombination.
Nature
382:551-555[CrossRef][Medline].
|
| 44.
|
Ouyang, H.,
A. Nussenzweig,
A. Kurimasa,
V. D. Soares,
X. L. Li,
C. Cordón-Cardó,
W. H. Li,
N. Cheong,
M. Nussenzweig,
G. Iliakis,
D. J. Chen, and G. C. Li.
1997.
Ku70 is required for DNA repair but not for T cell antigen receptor gene recombination in vivo.
J. Exp. Med.
186:921-929[Abstract/Free Full Text].
|
| 45.
|
Poltoratsky, V. P.,
X. Shi,
J. D. York,
M. R. Lieber, and T. H. Carter.
1995.
Human DNA-activated protein kinase (DNA-PK) is homologous to phosphatidylinositol kinases.
J. Immunol.
155:4529-4533[Abstract].
|
| 46.
|
Rufer, N.,
W. Dragowska,
G. Thornbury,
E. Roosnek, and P. M. Lansdorp.
1998.
Telomere length dynamics in human lymphocyte subpopulations measured by flow cytometry.
Nat. Biotechnol.
16:743-747[CrossRef][Medline].
|
| 47.
|
Samper, E.,
F. Goytisolo,
P. Slijepcevic,
P. van Buul, and M. A. Blasco.
2000.
Mammalian Ku86 prevents telomeric fusions independently of the length of TTAGGG repeats and the G-strand overhang.
EMBO Rep.
1:244-252[CrossRef][Medline].
|
| 48.
|
Smith, G. C. M., and S. P. Jackson.
1999.
The DNA-dependent protein kinase.
Genes Dev.
13:916-934[Free Full Text].
|
| 49.
|
Taccioli, G. E.,
A. G. Amatucci,
H. J. Beamish,
D. Gell,
X. H. Xiang,
M. I. Torres Arzayus,
A. Priestley,
S. P. Jackson,
A. Marshak Rothstein,
P. A. Jeggo, and V. L. Herrera.
1998.
Targeted disruption of the catalytic subunit of the DNA-PK gene in mice confers severe combined immunodeficiency and radiosensitivity.
Immunity
3:355-366.
|
| 50.
|
van Steensel, B.,
A. Smogorzewska, and T. de Lange.
1998.
TRF2 protects human telomeres from end-to-end fusions.
Cell
92:401-413[CrossRef][Medline].
|
| 51.
|
Vogel, H.,
D.-S. Lim,
G. Karsenty,
M. Finegold, and P. Hasty.
1999.
Deletion of Ku86 causes early onset of senescence in mice.
Proc. Natl. Acad. Sci. USA
96:10770-10775[Abstract/Free Full Text].
|
| 52.
|
Zhu, C. M.,
M. A. Bogue,
D. S. Lim,
P. Hasty, and D. B. Roth.
1996.
Ku86-deficient mice exhibit severe combined immunodeficiency and defective processing of V(D)J recombination intermediates.
Cell
86:379-389[CrossRef][Medline].
|
| 53.
|
Zhu, X. D.,
B. Kuster,
M. Mann,
J. H. Petrini, and T. de Lange.
2000.
Cell-cycle-regulated association of RAD50/MRE11/NBS1 with TRF2 and human telomeres.
Nat. Genet.
25:347-352[CrossRef][Medline].
|
| 54.
|
Zijlmans, J. M.,
U. M. Martens,
S. Poon,
A. K. Raap,
H. J. Tanke,
R. K. Ward, and P. M. Lansdorp.
1997.
Telomeres in the mouse have large interchromosomal variations in the number of T2AG3 repeats.
Proc. Natl. Acad. Sci. USA
94:7423-7428[Abstract/Free Full Text].
|
![[Feedback]](/icons/banner/feedbackACT.gif){kind=icon}
![[For Subscribers]](/icons/banner/subscriberACT.gif){kind=icon}
![[Archive]](/icons/banner/archiveACT.gif){kind=icon}
![[Search]](/icons/banner/searchACT.gif){kind=icon}
![[Contents]](/icons/banner/tocACT.gif){kind=icon}
Top
Abstract
Introduction
