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Molecular and Cellular Biology, April 1999, p. 3095-3102, Vol. 19, No. 4
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Atm Is Dispensable for p53 Apoptosis and Tumor
Suppression Triggered by Cell Cycle Dysfunction
Mai-Jing
Liao,1
Chaoying
Yin,1
Carrolee
Barlow,2
Anthony
Wynshaw-Boris,2 and
Terry
van Dyke1,*
Department of Biochemistry and Biophysics,
Lineberger Comprehensive Cancer Center, University of North Carolina at
Chapel Hill School of Medicine, Chapel Hill, North Carolina
27599,1 and Laboratory of Genetic
Disease Research, National Human Genome Research Institute, National
Institutes of Health, Bethesda, Maryland 208922
Received 6 July 1998/Returned for modification 1 September
1998/Accepted 13 January 1999
 |
ABSTRACT |
Both p53 and ATM are checkpoint regulators with roles in genetic
stabilization and cancer susceptibility. ATM appears to function in the
same DNA damage checkpoint pathway as p53. However, ATM's role in
p53-dependent apoptosis and tumor suppression in response to cell cycle
dysregulation is unknown. In this study, we tested the role of murine
ataxia telangiectasia protein (Atm) in a transgenic mouse brain tumor
model in which p53-mediated apoptosis results in tumor suppression.
These p53-mediated activities are induced by tissue-specific
inactivation of pRb family proteins by a truncated simian virus 40 large T antigen in brain epithelium. We show that p53-dependent
apoptosis, transactivation, and tumor suppression are unaffected by Atm
deficiency, suggesting that signaling in the DNA damage pathway is
distinct from that in the oncogene-induced pathway. In addition, we
show that Atm deficiency has no overall effect on tumor growth and
progression in this model.
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INTRODUCTION |
The p53 tumor suppressor
and ATM (mutated in human ataxia telangiectasia [AT]
disease; Atm in mice) are both cancer susceptibility genes
with roles in checkpoint regulation (9, 22, 23). Each is
associated with distinct human genetic disorders in which patients are
prone to cancer. Patients with Li-Fraumeni syndrome carry a mutant p53
allele and develop a variety of cancers, including mammary
adenocarcinomas, sarcomas, brain tumors, and leukemia (21,
33). The p53 gene is also mutated in about 50% of sporadic human
cancers (6, 11). AT is an autosomal recessive disease characterized by cerebellar degeneration, oculocutaneous
telangiectasia, retarded growth, infertility, sensitivity to ionizing
radiation (IR), and a high incidence of cancers, most commonly lymphoid malignancies (17, 30). The early deaths of most homozygous AT patients preclude an accurate assessment of the full tumor spectrum
and the frequency of ATM deficiency in humans. Thus, human disease
progression alone cannot predict whether p53 and ATM share tumor
suppressor pathways.
p53 is involved in the cellular responses to a variety of stress
signals, the best characterized of which is DNA damage (7, 32). In response to a given signal, p53 can induce cell cycle arrest or apoptosis, and these functions appear to be involved in its
ability to suppress tumorigenesis. p53 deficiency can promote tumor
growth by a reduction in the level of apoptosis, an event for which
there would be substantial selection (12, 25, 34). Alternatively (or in addition), since p53-deficient cells are prone to
genomic instability (20, 44), the loss of p53 responses may
promote tumor progression through the genetic alteration of other
cancer genes (8, 15, 16).
ATM is also involved in checkpoint regulation. It belongs to the
phosphatidylinositol-3' kinase superfamily, a family of signal transduction proteins with homology in their carboxyl kinase domains (29). In response to DNA damage, this 350-kDa protein kinase appears to be required for checkpoints in G1, S, and
G2 phases (22, 23). Cultured cells derived from
AT patients or from Atm-deficient mice are highly abnormal. These cells
grow slowly and exhibit senescence prematurely (2, 17, 41).
They demonstrate high rates of spontaneous apoptosis and a
hypersensitivity to IR (22). Genome instability
characterized by frequent chromosomal translocations and telomere
defects is also commonly observed in AT cells (31, 35).
Atm-deficient mice display many of the human AT phenotypes, such as
retarded growth, infertility, sensitivity to IR, neurological
dysfunction (although mild), and tumor proneness (2, 5, 40).
Evidence that ATM and p53 could act in the same pathway comes from
studies of cell lines derived from AT patients and of knockout mice.
Induction of p53 and G1 arrest in response to DNA damage is
impaired in AT cell lines (14) and in mouse
Atm
/ embryonic stem cells (41),
embryo fibroblasts, and thymus cells (1, 2), indicating that
ATM acts upstream of p53 in response to DNA damage. Both
p53/ (4, 13) and
Atm/ (2, 5, 40) mice develop
thymic lymphoma, also suggesting the possibility of a common thymocyte
tumor suppression pathway.
In addition to DNA damage, p53 is activated by many other signals, such
as hypoxia, low ribonucleoside triphosphate levels, and
oncogene-induced aberrant proliferation (7, 18).
Dysregulated cell cycle activity has been shown to signal p53-dependent
apoptosis and tumor suppression in vivo (12, 24, 25, 34). It
is not clear whether these different stress signals are transduced to
p53 via common or distinct upstream molecular pathways.
Based on the established link between Atm and p53 in response to DNA
damage, we addressed the role of Atm in p53-dependent apoptosis and
tumor suppression when induced by aberrant cell cycle activities by
using the transgenic TgT121 brain tumor model. T121 is a truncated simian virus 40 large T antigen that
binds and inactivates pRb and the related proteins p107 and p130
(27). Tissue-specific expression of this oncoprotein in
brain choroid plexus epithelium (CP) induces the aberrant proliferation
of these normally quiescent cells, and a measurable p53-dependent
apoptosis pathway that suppresses tumor growth is activated (Fig.
1A). Inactivation of p53 causes an 85%
reduction in CP apoptosis and accelerates tumor growth sevenfold
(34). This model provides a quantitative test for p53 tumor
suppression activities in vivo. In this study we assessed the impact of
Atm deficiency on p53-mediated apoptosis and tumor suppression in these
mice.
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FIG. 1.
Is Atm required for p53-dependent apoptosis and tumor
suppression in the TgT121 brain tumor model? (A) Transgenic
expression of T121 in CP inactivates pRb family proteins
(pRb-f) (including pRb, p107, and p130), resulting in abnormal
proliferation and tumorigenesis. As a result, p53 is activated, causing
apoptosis and attenuation of tumor growth (34). (B) Atm is
expressed in T121 CP. Western immunoblotting was performed
on tissue extracts by using a monoclonal antibody specific for ATM,
2C6. Lane 1, Atm/ spleen (negative control);
lanes 2 and 3, thymus and spleen tissues, respectively, of a wild-type
mouse (positive control); lane 4, TgT121 CP. Two resolvable
Atm-specific bands the size of mouse Atm are detectable in lanes 2 through 4 and are absent from the negative control. The position of a
175-kDa molecular mass marker is shown on the right.
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MATERIALS AND METHODS |
Mice.
TgT121 mice carry a transgene that
expresses T121 specifically in CP under the control of
lymphotropic papovavirus transcriptional signals (28).
T121 consists of the simian virus 40 T-antigen N-terminal
121 amino acids with 11 C-terminal missense residues (27).
The Atm/ mice carry a truncation mutation at
nucleotide 5790 caused by a PGKneo gene insertion (2).
TgT121 (C57BL/6 × DBA2) mice were bred with
Atm+/ mice (C57BL/6 × 129sv) to generate
(TgT121 × Atm+/) F1
mice. F1 mice were further intercrossed to generate
TgT121 Atm/ mice (C57BL/6 × DBA2 × 129sv). TgT121 and
Atm/ genotypes were determined by PCR
analysis of tail DNA. TgT121 screening has been described
previously (28). PCR primers were designed for genotyping
Atm/ mice. Primer pairs Atm-F (5'-GAC
TTC TGT CAG ATG TTG CTG CC-3') and Atm-B (5'-CGA ATT TGC AGG
AGT TGC TGA G-3') were used to identify the wild-type
Atm allele, and Atm-F and Atm-Neo (5'-GGG TGG GAT TAG
ATA AAT GCC TG-3') were used to identify the knockout allele by
performing 35 cycles of 94°C for 1 min, 55°C for 1 min, and 72°C
for 1 min. The Atm-F-Atm-B pair generates a 162-bp PCR product, and
the Atm-F-Atm-Neo pair generates a 441-bp PCR product.
Western blotting.
Western blotting analysis was carried out
as previously described (39). Two hundred micrograms of
protein from total cell lysates of fresh tissues was resolved by sodium
dodecyl sulfate-5% polyacrylamide gel electrophoresis (cross-linking
ratio, 29:1). Two independent anti-human ATM antibodies, 2C6
(3) and 473 (kindly provided by Eva Lee and Michael Kastan,
respectively), were used separately to detect Atm protein expression in
TgT121 CP. The results were the same with both reagents.
The enhanced chemiluminescence system (Amersham) was used according to
the manufacturer's instructions.
Histology, S-phase, and apoptosis assays.
Brain tissues were
fixed in 10% formalin, embedded in paraffin, and sectioned as
previously described (34). To examine tumor size, 6-µm
sections were taken from 10 successive layers at 100-µm intervals.
For histology assays, sections were stained with hematoxylin and eosin
as previously described (34). Bromodeoxyuridine (BrdU) labeling and immunostaining as well as the terminal
deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling
(TUNEL) apoptosis assay were completed as previously described
(34, 43). Quantification was made by averaging the
percentage of positive cells in 10 random fields at a magnification of
×400.
In situ RNA hybridization.
Sections (6 µm) were hybridized
with p21 or Bax antisense probes as previously described (26,
43). Probes were radiolabeled with 
-35S-UTP and
used at a concentration of 5 × 104 cpm
ml1. Autoradiography was conducted at 4°C for 3 days
for the p21 probe and at 4°C for 3 weeks for the Bax probe. Signal
densities were quantified with NIH Image 1.58. The threshold was set by using the sense probe signals as the background. Means were determined from 10 random areas of CP for each sample.
| |
RESULTS |
p53-dependent apoptosis does not require Atm.
A genetic
approach has been taken to determine the pathway by which p53-dependent
apoptosis and tumor suppression proceed in TgT121 mice. For
example, by assessing the rates of apoptosis and tumor growth in a
background with specific deficiencies, we previously determined that
E2F1 is upstream (26) and Bax is downstream (43)
of p53 in this system. The possibility that Atm could be active in
TgT121 CP is demonstrated by the detection of Atm in this
tissue by Western blotting analysis (Fig. 1B). A spleen extract from an
Atm/ mouse served as a negative control and
showed no specific proteins the size of Atm (Fig. 1B, lane 1). In
contrast, spleen and thymus tissues from a wild-type mouse (lanes 2 and
3) and CP from a TgT121 mouse (lane 4) contained a 350-kDa
Atm-specific doublet detectable with two independent ATM-specific
antibodies (the results presented in Fig. 1B were obtained with the 2C6
monoclonal antibody).
To examine whether Atm deficiency has a role in p53 tumor suppression
activities, we generated TgT
121
Atm/ mice through a series of crosses by
using TgT
121 (
28) and
Atm+/ (
2) mice. We first assessed
the effect of Atm deficiency on
T
121-induced p53-dependent
apoptosis by using the in situ TUNEL
assay (Fig.
2A). The CP apoptotic index (AI) was
determined for
brain sections from TgT
121
Atm/ mice, which were compared to
TgT
121 Atm+/+ littermates.
Previously, TgT
121 CP cells were shown to have an
average
AI of 7.3%, 85% of which requires functional p53 (
34).
In
the present study, the CP AI of TgT
121
Atm+/+ littermate controls was similar,
averaging 6.69% ± 0.17% (Fig.
2B). The CP of control
Atm/ mice appeared to be normal, with no
apoptotic activity (Table
1). The AI in
TgT
121 Atm/ CP was similar to
that of TgT
121 Atm+/+ mice (7.17% ± 0.99%) (Fig.
2; Table
1). This is in stark contrast
to the dramatic
decrease in AI caused by p53 deficiency (Table
1; Fig.
2C)
(
34). Thus, in this system, p53-dependent apoptosis
in
response to abnormal proliferation does not require Atm.
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FIG. 2.
p53-mediated apoptosis does not require Atm. (A)
Apoptotic cells in CP (arrows) were detected by the TUNEL assay. No
qualitative changes were detected between TgT121 and
TgT121 Atm/ CP tumor cells. (B)
Quantitative apoptotic indices in TgT121 and
TgT121 Atm/ CP. The percentages
of apoptotic cells were determined for TgT121 (open bars)
and TgT121 Atm/ (solid bars)
littermates at different ages. Each bar in the left panel represents
the averaged counts from 10 fields of one sample from one mouse at the
specified age. The averages of all four mice are shown at the right.
The error bars represent the standard deviations among microscopic
fields (left) or among mice (right). (C) Impact of Atm deficiency on
apoptosis compared with impact of p53 and E2F1 deficiency. Atm
deficiency has no effect on apoptosis in TgT121 CP cells,
while p53 and E2F1 account for 85 and 80% of the apoptosis,
respectively (26, 34).
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|
Intact p53 transactivation activity in the absence of Atm.
To
further assess the impact of Atm deficiency on p53 function, we
examined p53 transactivation activity in TgT121
Atm/ CP. We previously showed that
T121 expression in the CP induces the p53-regulated genes
bax (43), p21 (26), and
mdm2 (26) in a p53-dependent manner. To assess
the p53 transactivation activity in the absence of Atm, bax
and p21 transcript levels were measured in
TgT121 Atm/ and
TgT121 Atm+/+ brain sections by in
situ RNA hybridization (Fig. 3). Samples from young mice (5 to 7 weeks) were analyzed to avoid the influence of
spontaneous genetic changes during tumor progression. Quantitative analysis indicated that p53-dependent p21 and bax
RNA levels in the CP remain unchanged in the absence of Atm (Fig. 3A
through D). The levels of p21 and bax transcripts
in TgT121 Atm/ CP were 99% ± 4.8% and 105% ± 8%, respectively, of those of TgT121 Atm+/+ littermates (Fig. 3G). All p21
expression in these cells was dependent on p53 activity (Fig. 3E), as
was much of the bax expression, as previously observed (Fig.
3F). In this system, Bax is involved in p53-dependent apoptosis
(43), while p21 is not (our unpublished results). Thus, Atm
is dispensable for T121-induced p53 transactivation functions that are apoptosis dependent as well as independent.
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FIG. 3.
Atm deficiency does not affect p53 transactivation
function in CP. Representative in situ RNA hybridization signals are
shown for p21 (A, C, and E) and bax (B, D, and F)
expression. p21 RNA is readily detectable in
TgT121 (A) as well as in TgT121
Atm/ (C) CP. bax RNA levels are
also equally expressed in TgT121 (B) and TgT121
Atm/ (D) cells. bax and
p21 expression in TgT121 CP are both p53
dependent, as seen in TgT121
p53/ cells (E and F). (G) Quantitative
comparisons of RNA levels; signals in TgT121 are designated
as 100%. The signal detected in CP by using a bax or
p21 sense probe was at about the background level, ensuring
the specificity of the assay. Ten fields of each sample were analyzed.
Standard errors in each field are less than 10% of the relative mean
value.
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Effects of Atm deficiency on tumor cell proliferation and overall
tumor growth.
Although the above results show that Atm is not
required for p53-dependent apoptosis or transactivation, Atm could
affect CP tumor growth by other mechanisms. For example, Atm deficiency could diminish tumor growth since Atm/
fibroblasts exhibit poor growth and a reduced life span in culture (2, 41). Alternatively, Atm inactivation could
accelerate tumor growth through genetic instability, as proposed for
Atm deficiency-induced lymphoma and leukemia (35).
To determine whether Atm deficiency has an impact on CP tumor cell
proliferation, we measured S-phase indices by in vivo BrdU
incorporation (Fig.
4A). Mice were
analyzed at various times during
early tumor growth (5 to 14 weeks) to
circumvent selective changes
during tumor progression. No difference
was detected in the percentage
of S-phase CP in TgT
121
Atm/ and TgT
121
Atm+/+ littermates (Table
1). TgT
121
Atm/ CP averaged 10.6% ± 3.4% of cells in
S phase, while TgT
121 Atm+/+ CP
averaged 10.3% ± 2.8% of cells in S phase (Fig.
4B). Therefore,
unlike fibroblast growth in culture, Atm deficiency had no measurable
impact on CP tumor cell proliferation in vivo.
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FIG. 4.
Effects of Atm deficiency on tumor cell proliferation.
TgT121 and TgT121
Atm/ CP were stained for BrdU incorporation
to measure proliferation rates. (A) Representative views of CP from
TgT121 and TgT121
Atm/ 7-week-old littermates stained for BrdU
(red), with nuclei counterstained by hematoxylin (blue). No
BrdU-staining cells are present in the surrounding brain parenchyma
(BP). (B) Percentage of S-phase cells in TgT121 (open bars)
and TgT121 Atm/ (solid bars) CP.
Left, percentage of proliferating cells in paired littermates (each bar
represents brain sections from one mouse; error bars represent the
standard deviations among sets of 10 microscopic fields); right,
averaged percentage of S-phase cells in these age-matched groups shown
at the left (error bars represent standard deviations among individual
mice).
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Although the apoptotic and proliferative indices of TgT
121
CP were not affected by
Atm inactivation, an effect on tumor
morphology
and progression was possible. To determine the overall
impact
of Atm deficiency on tumor growth, the survival times, tumor
sizes,
and morphologies of TgT
121
Atm/ mice were compared to those of
TgT
121 Atm+/+ littermates. Control
TgT
121 and Atm-deficient mice developed
different tumor
types and had different average survival times.
TgT
121 mice
died of brain tumors with an average survival time
of 31 weeks, whereas
Atm-deficient mice died of thymoma with an
average survival time of 20 weeks (Table
1). Like
Atm/ mice, all
TgT
121 Atm/ mice developed
thymic lymphoma (average survival time of 23 weeks
[Table
1]). The
difference between thymoma development in
Atm/ mice and that in TgT
121
Atm/ mice is not statistically significant
(
P = 0.5115 in an unpaired
two-tailed
t
test) and could be due to background strain differences
(C57BL/6 × 129sv versus C57BL/6 × DBA2 × 129sv) or due to
T
121 expression in thymocytes (
28).
Although TgT
121 Atm/ mice
succumbed to thymic lymphoma prior to the terminal age anticipated for
mice with brain tumors, their
lengthy survival indicates that Atm
deficiency did not substantially
accelerate the growth of
T
121-induced brain tumors. CP tumors
present in
TgT
121 Atm/ mice at the time of
autopsy were comparable in size and morphology
to those in
TgT
121 mice of similar ages (data not shown). Furthermore,
assessment of tumor sizes at 4 to 20 weeks showed no significant
differences between TgT
121 Atm+/+
and TgT
121 Atm/ littermates
(Fig.
5). The CP of
Atm/ mice was morphologically normal. These
results are consistent
with the observation that both apoptosis and
proliferation were
unaffected by Atm deficiency. In sharp contrast,
TgT
121 p53/ mice develop large
tumor masses within 4 weeks (Fig.
5E; Table
1) (
34).
Analysis of TgT
121 Atm+/ mice also
showed that Atm deficiency did not promote tumor progression.
Tumor
growth in TgT
121 p53+/ mice
progresses from slow growth to highly aggressive and angiogenic
growth
within 7 weeks, leading to the death of the mice by 12
weeks of age
(Fig.
5D) (
34). This occurs in all mice and correlates
with
a high frequency of p53 loss of heterozygocity. In contrast,
no such
acceleration was observed in TgT
121
Atm+/ mice (Fig.
5H).
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FIG. 5.
Effects of Atm deficiency on CP tumor growth and
progression. Sizes of the CP masses (arrows) are shown.
TgT121 mice at 7 weeks (B) and 14 weeks (C) are compared to
TgT121 Atm/ littermates (F and
G, respectively). Note that p53 deficiency greatly accelerated tumor
growth as indicated by the mass size at 4 weeks (E versus A). CP tumor
progression to aggressive angiogenic states was observed in
TgT121 p53+/ mice (D) but not in
TgT121 Atm+/ mice (H). These views
represent the largest mass present among step sections sampled from the
full brain to ensure a fair comparison of tumor sizes.
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DISCUSSION |
Atm and p53.
In this study we explored the possibility that
Atm functions in a p53 apoptosis and tumor suppression pathway that is
induced via aberrant proliferation rather than DNA damage. The
molecular signals involved in p53 induction in this case are largely
unknown. One possibility is that aberrant S-phase activity generates
DNA damage-like signals, in which case the pathways could be
coincident. Here, we show that Atm deficiency does not impair p53
activation by inappropriate cell cycle activity in brain epithelium.
The approach used in this study to study Atm has been used in previous studies to identify both upstream (26) and downstream
(43) effectors in this pathway. E2F1 deficiency causes an
80% inhibition of p53-dependent apoptosis (Fig. 2C) as well as
inhibition of p53 transactivation function, indicating that E2F1 lies
upstream of p53 (26). Therefore, inactivation of pRb
proteins by T121 leads to E2F1 activation, which then
induces p53 function (26). In contrast, this report shows
that Atm is not required in this pathway
p53-dependent apoptosis,
transactivation, and tumor suppression are fully active in the absence
of Atm. Together, these data indicate that different stress signals are
transduced to p53 via distinct pathways.
Comparison of these results with those of previous reports addressing
the role of ATM in p53-dependent activities largely
supports the idea
that the distinction observed here is based
on the inducing signal
rather than cell type or biological response
(i.e., apoptosis or growth
arrest). So far, ATM has been implicated
only in DNA damage-induced p53
responses, including the induction
of both growth arrest and apoptosis.
Atm is required for DNA damage-induced
p53 induction and G
1
arrest in human (
23) and mouse (
2) fibroblasts
and in mouse embryonic stem cells (
41) and thymus tissue
(
1).
It is also required for IR-induced p53-dependent
apoptosis of
neurons in the developing central nervous system, since
the irradiation
of newborn mice induces widespread central nervous
system apoptosis,
coincident with p53 induction. This apoptosis is
dramatically
reduced in both p53-deficient and Atm-deficient mice
(
10).
In the thymus, IR-induced p53-dependent apoptosis is not Atm dependent
in vivo (
1,
10), although the p53-dependent G
1/S
checkpoint does require Atm (
1). Therefore, within a given
tissue, distinct p53-mediated biological effects are induced by
apparently distinct pathways upstream of p53 (
1). Two
reports
show a partial reduction in the IR-induced p53-dependent
apoptosis
of
Atm/ thymus cells
(
41) or thymocytes (
37). This contradiction
could
indicate differences in thymocyte subpopulations or could
result from
in vitro versus in vivo approaches. In the present
study, we have
examined in vivo apoptotic responses to show that
Atm is dispensable
for p53-mediated apoptosis and tumor suppression
in brain epithelium.
We cannot exclude the possibility that Atm-related
factors fully
compensate for the absence of
Atm.
Whether Atm and p53 participate in the same tumor suppression pathways
in other cell types is not known. Although both Atm-
and p53-deficient
mice develop thymic lymphomas with high frequency,
in
Atm
p53 double-null mice, tumor growth is accelerated (
37,
42), indicating that Atm and p53 cooperate in thymocyte tumor
suppression, rather than fall within a linear pathway. In addition,
V(D)J recombination-associated translocations are frequent in
thymomas
from Atm-deficient mice (
2) but not in thymomas from
p53-deficient mice (
19). Therefore, in mouse thymocytes,
where
both Atm and p53 are proven tumor suppressors, the pathways may
be
distinct.
Atm and tumor growth.
In the present study Atm deficiency did
not affect CP tumor cell proliferation or tumor growth despite the fact
that the proliferation of Atm/ fibroblasts
was impaired and senescence occurred prematurely. This lack of Atm
effect on CP tumor cell proliferation could reflect cell-type-specific
differences. In Atm/ fibroblasts,
proliferative defects can be rescued by the inactivation of either
p21 or p53 (36, 38, 42). CP tumor
cells express p21 abundantly and possess functional p53.
However, pRb (a known target of cyclin-dependent kinases inhibited by
p21) is inactivated by T121 in CP tumor cells, possibly
masking any growth-inhibitory effects of Atm deficiency.
Finally, we considered the possibility that genetic instability induced
by Atm deficiency could result in measurable effects on tumor
progression. TgT121 p53+/ CP
tumors progress to highly aggressive states with frequent p53 loss of
heterozygocity (34) and widespread aneuploidy (our unpublished results). No such accelerated progression was observed in
TgT121 Atm+/ mice.
In summary, our results suggest that distinct signal transduction
pathways may induce p53, depending on the cellular insults.
While Atm
appears to be involved in p53 activation by DNA damage,
it is not
required for p53 activation by aberrant cell cycle activity
in brain
epithelium. Furthermore, when these tumors are initiated
by the
inactivation of the pRb family, Atm deficiency has no further
impact on
tumor growth and
progression.
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ACKNOWLEDGMENTS |
We thank Le Zhang for excellent technical assistance, Michael
Kastan and Eva Lee for providing reagents, and Eva Lee for
communication of unpublished data.
This work was supported by grants from the National Institutes of
Health (CA65773 and CA46283) to T.V.D.
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FOOTNOTES |
*
Corresponding author. Mailing address: CB #3280,
Fordham Hall, UNC-CH, Chapel Hill, NC 27599-3280. Phone: (919)
962-2148. Fax: (919) 962-4296. E-mail:
tvdlab{at}med.unc.edu.
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Molecular and Cellular Biology, April 1999, p. 3095-3102, Vol. 19, No. 4
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
