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Journal of Virology, March 2001, p. 2185-2193, Vol. 75, No. 5
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.5.2185-2193.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Analysis of p53 Inactivation in a Human T-Cell
Leukemia Virus Type 1 Tax Transgenic Mouse Model
Toni
Portis,1
William J.
Grossman,1
John C.
Harding,1
Jay L.
Hess,2 and
Lee
Ratner1,*
Departments of Medicine, Pathology, and
Molecular Microbiology, Washington University School of Medicine,
St. Louis, Missouri 63110,1 and
Department of Pathology and Laboratory Medicine, University
of Pennsylvania School of Medicine, Philadelphia, Pennsylvania
191042
Received 18 September 2000/Accepted 6 December 2000
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ABSTRACT |
Human T-cell leukemia virus type 1 (HTLV-1) is the etiologic agent
of adult T-cell leukemia/lymphoma (ATLL). The HTLV-1 Tax protein has
been strongly linked to oncogenesis and is considered to be the
transforming protein of this virus. A Tax transgenic mouse model was
utilized to study the contribution of p53 inactivation to Tax-mediated
tumorigenesis. These mice develop primary, peripheral tumors consisting
of large granular lymphocytic (LGL) cells, which also infiltrate the
lymph nodes, bone marrow, spleen, liver, and lungs. Primary Tax-induced
tumors and tumor-derived cell lines exhibited functional inactivation
of the p53 apoptotic pathway; such tumors and tumor cell lines were
resistant to an apoptosis-inducing stimulus. In contrast,
p53 mutations in tumors were found to be associated with
secondary organ infiltration. Three of four identified mutations
inhibited transactivation and apoptosis induction activities in vitro.
Furthermore, experiments which involved mating Tax transgenic mice with
p53-deficient mice demonstrated minimal acceleration in initial tumor
formation, but significantly accelerated disease progression and death
in mice heterozygous for p53. These studies suggest that
functional inactivation of p53 by HTLV-1 Tax, whether by mutation or
another mechanism, is not critical for initial tumor formation, but
contributes to late-stage tumor progression.
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INTRODUCTION |
Human T-cell leukemia virus type 1 (HTLV-1) is the causative agent of adult T-cell leukemia/lymphoma
(ATLL), a highly aggressive and fatal CD4+
T-lymphoproliferative malignancy that occurs in approximately 1 to 5%
of HTLV-1-infected individuals after a long latency period (33). The HTLV-1 Tax protein is a potent transcriptional
transactivator of both viral and cellular gene expression. Tax normally
exerts its effects on viral gene expression by activating cellular
transcription factors which, in turn, bind Tax responsive elements
located in the viral long terminal repeat (4). Tax has
also been shown to transactivate cellular gene transcription by acting
on several structurally unrelated cellular proteins, including cyclic
AMP (cAMP) response element/activating transcription factor (CREB/ATF) members, NF-
B/Rel proteins, and serum response factors (1, 10,
11, 13).
It has been suggested that Tax mediates cellular transformation by
stimulating proliferation and/or inhibiting apoptosis. Tax upregulates
cyclin D2 expression and stimulates G1-to-S-phase transition through upregulated CDK4 and CDK6 activity (37,
39). Tax has also been shown to directly bind and affect the
activity of a number of cell cycle regulatory proteins, such as p15,
p16, and cyclin D3 (27, 29, 41, 42). In
transient-transfection experiments, Tax transactivates the
proliferating cell nuclear antigen promoter and transrepresses
expression of p18 and p56lck, as well as the
apoptosis-inducing gene bax, through E-box elements (3, 23, 35, 42). Other reports indicate that Tax
expression induces interleukin 2 (IL-2)-independent proliferation and
resistance to apoptosis in IL-2-dependent cutaneous T-cell
leukemia/lymphoma type 2 (CTLL-2) cells (17). This
resistance is not associated with repression of bax but with
transactivation of the antiapoptotic bcl-xl protein through NF-B
elements located in the promoter region (44).
The tumor suppressor protein p53 plays a critical role in cell cycle
regulation, DNA repair, and apoptosis. In response to DNA damage, p53
activates a number of genes involved in cell cycle arrest or apoptosis,
such as p21 (WAF1) and bax (12, 24). p53 mutations occur in >50% of all human cancers and in
leukemic cells of >30% of ATLL patients. These mutations are
associated with the accumulation of additional genetic alterations and
chromosomal abnormalities, resulting ultimately in immortalization
(6, 30). Certain hot spots of p53 mutations
occur more frequently in particular types of tumors; however, most
involve exons 5 through 8, a highly conserved DNA binding domain
critical for p53 function (8). Although p53 is
not usually mutated in cells transformed by HTLV-1 in vitro, recent
reports have suggested that wild-type p53 protein is stabilized and
functionally impaired in these cells, resulting in reduced induction of
p53-responsive genes (5, 31, 34). Unlike adenovirus EIB
55K, simian virus 40 large T antigen, and human papillomavirus (HPV) E6
viral proteins, which all bind p53 and inhibit its function, HTLV-1 Tax
does not appear to directly interact with p53 (38, 47).
Instead, HTLV-1 is thought to alter posttranslational modification of
p53, abrogating its function (32).
We have previously demonstrated that expression of HTLV-1 Tax in the
mature lymphoid compartment in mice is sufficient for lymphoma
development. These mice express Tax from the human granzyme B promoter,
limiting its production to cytotoxic T-lymphocyte (CTL) and natural
killer (NK) cells. The mice develop primary, peripheral lymphomas at 6 to 9 months of age which infiltrate the lymph nodes, bone marrow,
spleen, liver, and lungs (14). Tumor cells demonstrate
elevated production of IL-1
, IL-1
, gamma interferon,
granulocyte-macrophage colony-stimulating factor (IL-15, IL-10, and
IL-6), and constitutive cell surface expression of ICAM-1, LFA-1, and
VLA-4 (15; T. Portis and L. Ratner, unpublished data). In
this study, we utilized Tax transgenic mice to determine the
contribution of p53 inactivation to Tax-induced tumorigenesis. Accumulation of specific mutations in the DNA binding domain of p53 was
associated with tumor dissemination. Three of four mutations analyzed
were shown to inhibit p53-specific transactivation and apoptosis in
vitro. Interestingly, fresh tumors and tumor-derived cell lines from
Tax transgenic mice were resistant to irradiation-induced apoptosis;
however, transcriptional activation of downstream p53 responsive genes
appeared normal. In vivo, we found that tumor formation was not
accelerated in p53+/
Tax+ mice compared to
that in p53+/+ Tax+ mice; however,
p53 heterozygosity was associated with formation of
multiple tumors and accelerated mortality. This, together with the
correlation between frequency of p53 mutation and tumor dissemination, suggests that p53 inactivation is a late event in Tax-mediated tumorigenesis, possibly accounting for rapid dissemination and disease
progression. Furthermore, Tax-induced events early in tumorigenesis
likely involve inhibition of apoptosis, possibly through downstream
effectors in the p53 pathway.
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MATERIALS AND METHODS |
Mice.
Granzyme B-Tax transgenic mice (Tax+) were
generated as previously described (14). Mice containing a
homozygous deletion in p53 (p53/) were purchased from
Jackson Laboratories (18). Tax+ mice were
mated with p53/ mice, and the resulting
p53+/ Tax+ progeny were mated for production
of F2 progeny. F2 mice were monitored weekly
for rates of tumor formation, morbidity, and mortality. Pathological
characteristics of tumors were compared among p53+/+
Tax+, p53+/ Tax+,
p53/ Tax+, p53+/+,
p53+/, and p53/ transgenic littermates.
All genotyping was performed as described previously (14;
Jackson Laboratories protocol). Tissues were fixed in 10%
neutral-buffered formalin, embedded in paraffin for sectioning, and
stained with hematoxylin and eosin as described previously
(14). All mice were bred and maintained under
pathogen-free conditions in accordance with Washington University
animal care guidelines. Kaplan-Meier analysis and statistical
calculations were carried out using the SPSS statistical analysis
program (SPSS, Inc.).
Tissues and cell lines.
Fresh tumors and tissues removed
from mice were released into medium supplemented with 10% fetal bovine
serum, 1% L-glutamine, 1% sodium pyruvate, and 1%
penicillin-streptomycin (RPMI medium; Life Technologies). Erythrocytes
in splenocyte preparations were lysed with 155 mM ammonium chloride and
washed prior to culture. The tumor-derived F8 and SC large granular
lymphocytic (LGL) cell lines have been described elsewhere and were
maintained in RPMI medium (14, 15). Abelson murine
leukemia virus (MLV)-transformed pre-B-cell lines containing wild-type
(204-3-1) and mutant (143-2M) p53 were provided by Naomi Rosenberg
(Tufts University, Boston, Mass.) (43) and maintained in
RPMI medium. The human H1299 non-small-cell lung carcinoma cell line
was provided by Rainer Brachmann (Washington University, St. Louis,
Mo.) and maintained in Dulbecco modified Eagle medium (DMEM) (Life
Technologies) supplemented with 10% fetal bovine serum, 1%
L-glutamine, and 1% sodium pyruvate plus 1%
penicillin-streptomycin (called DMEM). The SAOS-2 osteosarcoma cell
line was provided by Doug Dean (Washington University) and maintained
in DMEM.
PCR-single strand conformation polymorphism (PCR-SSCP)
analysis.
Genomic DNA was extracted from tumor cells in buffer
containing 100 mM NaCl, 10 mM EDTA (pH 8), 50 mM Tris-Cl (pH 7.6), 1% sodium dodecyl sulfate (SDS), and 0.5 mg of proteinase K/ml. Following an overnight incubation at 50°C, genomic DNA was phenol-chloroform extracted and precipitated with a 1/10 volume 3 M sodium acetate (pH
5.5) and 2 volumes of ethanol. DNA from nontransgenic mice and cells
containing known p53 mutations were used as controls when available
(2).
Primers used for amplification of exons 5 to 8 of p53 have been
described previously (2). Briefly, 200 ng of genomic DNA was added to reaction mixtures containing 0.15 µg each of sense and
antisense primers (IDT, Inc.), 1× PCR buffer, 1 µCi of
[-32P]dCTP (ICN), 0.05 mmol of deoxynucleoside
triphosphates/liter, 25 mmol of MgCl2/liter, and 1 U of
Taq DNA polymerase (Life Technologies). PCR was run as
follows: 3 min at 95°C, 30 cycles of 1 min at 95°C and 1 min at
64°C, and a final extension of 5 min at 64°C. After amplification,
PCR products were denatured for 2 min at 94°C and immediately placed
on ice. Samples were loaded on 0.75× Mutation Detection Enhancement
gels (FMC), run at 8 W in 4°C for 6 h, and exposed to X-ray film.
Mutant DNA fragments were excised from gels, and DNA was eluted in 500 mM ammonium acetate-10 mM magnesium acetate-1 mM EDTA-0.1%
SDS.
Aliquots of samples were then subjected to another round
of PCR-SSCP
analysis utilizing the appropriate primers to confirm
the absence of
wild-type p53 contamination and cloned into PCR-TRAP
vectors according
to the manufacturer's specifications (GenHunter).
Vector-specific
primers were utilized for automated, PCR-based
sequence analysis (P-Y.
Kwok, Washington University). Wild-type
p53 sequences from each exon
were cloned in parallel for use as
controls. The Universal Mutation p53
database (
16) was utilized
to calculate the number of
times each particular mutation has
been documented in human
cancers.
RT-PCR and plasmid construct generation.
Total RNA was
extracted from wild-type (204-3-1) and mutant (143-2M) p53-containing
cell lines using TRI reagent (Sigma). Reverse transcriptase (RT)
reactions were performed according to the Superscript II RT protocol
(Life Technologies). A portion of the RT product was used in standard
PCRs, including 0.5 µg each of p53 sense (S)
(5'-GGAATTCAGGCCCTCATCCT-3') and antisense (AS)
(5'-GGAATTCAGCCCTGAAGTCATAAGA-3') primers containing
EcoRI linkers to amplify nucleotides 101 to 1399. Site-directed mutagenesis was performed by using PCRs to independently
amplify 5' and 3' regions of p53. Primer sets consisted of either sense
or antisense primers (above) combined with primers containing
single-point mutations. Diluted aliquots (1:100) of the modified 5' and
3' p53 sequences were then combined and reamplified by PCR using p53
sense and antisense primers.
Mutant and wild-type p53 PCR products were cloned into TA vectors and
subsequently cloned into pcDNA3 expression vectors at
EcoRI
sites (Invitrogen). All clones were sequenced to verify
the presence of
specific mutations. Luciferase reporter plasmids
were provided by Naomi
Rosenberg (Tufts University) (
43). The
p21p construct
contains the complete p21 promoter region upstream
of luciferase while
p21p
1.1 is missing 1.1 kb of the 5' sequence
that is specific for
p53 transactivation of the p21 promoter (
9).
Transfections, transactivation analysis, and apoptosis
studies.
H1299 cells were transfected with 1 µg of p53
expression plasmid and 0.2 µg of reporter plasmid in serum-free
medium (Optimem) using Lipofectamine reagent (Life Technologies). pcDNA
3-CAT plasmids (0.2 µg) were cotransfected to measure transfection
efficiency by chloramphenicol acetyltransferase (CAT) assay
(26). Lipofectamine-DNA precipitates were left in culture
medium for 16 h. Cells were then re-fed with DMEM, and 24 h
later, cell lysates were analyzed for luciferase activity using a
luminometer (MGM Instruments).
SAOS-2 cells were transfected with 5 µg of wild-type or mutant p53
expression plasmids by calcium phosphate precipitation
methods
described previously (
7). Cells were cotransfected
with
pDsRed1-N1 plasmids containing red fluorescent protein (RFP;
Clontech)
and p53 expression plasmids and were harvested 36 h
posttransfection. RFP-positive apoptotic cells were measured by
fluorescence labeling of fragmented DNA using the FlowTACS FITC
protocol (Trevigen, Inc.). Dual positive cells were analyzed by
fluorescence-activated cell sorter (FACS) analysis on a FACScan
flow
cytometer (Becton
Dickinson).
Fresh tumor suspensions were treated with 2,000 rads of
-irradiation
and placed in RPMI medium. Five hours postirradiation,
10
5
cells were stained with fluorescein isothiocyanate (FITC)-conjugated
antibody against annexin V as described by the manufacturer
(Pharmingen).
Apoptotic cells were measured by FACS analysis on a
FACScan flow
cytometer (Becton Dickinson). Total RNA was also extracted
2 h
postirradiation using TRI reagent, and RT-PCRs were performed
as described above using primers specific for p21, bax, mdm2,
p53,
GAPDH (glyceraldehyde-3-phosphate dehydrogenase), and HGPRT
(hypoxanthine/guanine phosphoribosyl transferase). The primers
and
sequences were as follows: p21 S (5'GGTCCCGTGGACAGTGAGCA-3')
and p21 AS (5'-GTCAGGCTGGTCTGCCTCCG-3'), bax S
(5'-CCAGCTCTGAACAGATCATG-3')
and bax AS
(5'-TCAGCCCATCTTCTTCCAGA-3'), mdm2 S
(5'-CAAGCACCTCACAGATTCCA-3')
and mdm2 AS
(5'CATCCTCATCTGAGAGCTCG-3'), and GAPDH S
(5'-CCATCACCATCTTCCAGGAGCGAG-3')
and GAPDH AS
(5'-CACAGTCTTCTGGGTGGCAGTGAT-3'). PCR products were
separated by electrophoresis and visualized by UV light exposure.
Fold
activation of transcripts was quantitated by normalizing
the
intensities of p21, bax, mdm2, and p53 products to that of
GAPDH.
Western blottings.
Total cellular protein was prepared by
lysing cells in a mixture containing 50 mM Tris-Cl (pH 7.5), 5 mM EDTA,
150 mM NaCl, 1% Triton X-100, 10 µg of aprotinin/ml, 0.5 mM
phenylmethylsulfonyl fluoride, and 5 µg of pepstatin/ml. Five
micrograms of protein was immunoprecipitated with monoclonal antibodies
specific for mutant p53 (Ab-3) and wild-type p53 (Ab-11) (both from
Oncogene Sciences) or pooled anti-Tax monoclonal antibodies (no.
168A51-2, 168A51-42, and 168B17-46-34; AIDS Reagent Program, Rockville, Md.). Immunoprecipitated proteins were fractionated on SDS-10% acrylamide denaturing gels and electroblotted to nitrocellulose membranes by standard techniques (MSI). Immunoblotting was performed using antibodies to p53 or Tax diluted 1:500, followed by treatment with goat anti-mouse alkaline phosphatase-conjugated secondary antibody
(1:3,000; Sigma) and visualization by enhanced chemiluminescence (Amersham).
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RESULTS |
p53 mutations are present in tumors from Tax transgenic
mice.
Since p53 mutations have been documented in
tumors from ATLL patients, we utilized PCR-SSCP analysis to determine
whether similar mutations are present in tumors from HTLV-1 Tax
transgenic mice. Genomic DNA from a panel of tumors and tumor-derived
cell lines was used for this PCR-based assay, which detects
conformational intrastrand differences in DNA with a different
sequence. The primers used were specific for exon 1 and exons 5 to 8 of
murine p53. Exons 5 to 8 comprise the p53 core
domain, which contains sequence-specific DNA binding activity and is
necessary for transactivation of genes involved in cell cycle arrest
and apoptosis. Studies have shown that most p53 point
mutations occur in this region and result in the loss of functional p53
due to destabilization of the three-dimensional protein structure
(8).
A representative PCR-SSCP gel of exon 6, showing migration of wild-type
and mutant
p53 DNA strands in tumors from Tax transgenic
mice, is presented in Fig.
1. The
majority of
p53 genes appear
to be wild type, which may
reflect the heterogeneity of the tumor
samples or the fact that the
mutations are not present in the
majority of tumor cells or are only in
one allele of
p53. Spleen
and lung tissue also contain
significant numbers of normal, nonmalignant
cells; however, biological
clones grown from tumors show the same
predominance of wild-type
p53 (data not shown). Mutations concentrated
in exons 5 to 8 of
p53 were initially identified by PCR-SSCP analysis
in 3 of 7 primary, peripheral tumors (43%) and 10 of 11 sites
of
dissemination (91%), including spleen, lymph nodes, lung, and
liver
(Table
1). No mutations were found in the
less mutable
exon 1 of
p53 in any of the mice tested (data
not shown). Two
tumor-derived LGL cell lines, F8 and SC, developed IL-2
independence
after prolonged growth in vitro (
15). The
cell lines exhibited
the same mutations in exons 6 and 7 of
p53 (Fig.
1 and data not
shown). These data suggest a
correlation between
p53 mutation
and late-stage tumor
progression.
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FIG. 1.
Identification of mutated p53 alleles in tumors from Tax
transgenic mice. PCR-SSCP analysis was performed on tumors and
IL-2-independent tumor-derived cell lines from Tax transgenic mice
using primers specific for exons 1, 5, 6, 7, and 8 of murine p53. This
representative PCR-SSCP gel of exon 6 shows the migration of wild-type
p53 (wt) from nontransgenic tail DNA (lane 1) and mutated p53 (mu) in
tumors (lanes 4 to 9) and tumor-derived cell lines (lanes 2 and 3) from
Tax transgenic mice.
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Abnormally migrating bands on PCR-SSCP gels were then extracted,
subjected to another round of PCR-SSCP analysis, cloned into
plasmid
vectors, and sequenced. Although sequence analysis determined
that
various point mutations were present throughout the
p53 core
domain, four specific mutations in exons 6 and 7 arose frequently
in
tumors from several Tax transgenic mice (Table
1). These mutations
included P203A, E228G, N239S, and G244R. DNA from tumor samples
was
digested with enzymes specific for restriction sites either
generated
or deleted as a result of mutation in order to verify
that they were
indeed present in genomic DNA (data not shown).
Some primary and
disseminated tumors contained more than one
p53 mutation;
however, only one exon at a time could be analyzed,
making it difficult
to determine the relative levels of each mutation
in tumor samples. The
IL-2-independent F8 and SC tumor-derived
cell lines contained both
P203A and N239S
mutations.
The Universal Mutation p53 database, which documents more than 10,000
p53 mutations occurring in human cancers (
16),
was
utilized to calculate the number of times a nucleotide change
has
been documented at that location. As shown in Table
1, these
residues
are frequent sites of mutation in human cancers. The
P203A and E228G
mutations are located at critical turns between
highly twisted
-strands of the p53 core domain while the N239S
and G244R mutations
are located in the L3 loop, a critical area
of p53 protein-DNA contact
and frequent site of mutation (
8).
Individual mutations inhibit p53 function in vitro.
In order
to examine the effects of the individual mutations on p53
transactivation and induction of apoptosis, we recreated each mutation
separately by PCR-based site-directed mutagenesis. The resulting mutant
p53, as well as wild-type p53, DNA sequences were
cloned into pcDNA3 expression plasmids. A functionally inactive p53 mutant (C170W) from the 143-2M cell line was cloned in
parallel (43). The p53 expression plasmids were
cotransfected into p53 null H1299 cells along with constructs
expressing the luciferase gene under the p53 responsive p21 promoter
(p21p) (9). Identical luciferase constructs lacking the
p53-specific response element (p21p1.1) (9) were used
as controls for specificity of p53 transactivation. Equivalent levels
of p53 expression and transfection efficiency were verified by Western
blot analysis and CAT assay, respectively (data not shown). As shown in
Fig. 2A, wild-type p53-specific
transactivation of p21p was fivefold over that of the deletion
construct, p21p1.1, whereas the control mutant (C170W) transactivated both promoters equally well. The N239S mutant displayed transactivation levels similar to that of the control mutant. The E203A
and G244R mutants displayed lower (1.8- to 3-fold) levels than
wild-type p53, while the E228G mutation did not appear to be defective
in transactivation activity.
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FIG. 2.
Individual p53 mutants demonstrate variable levels of
p53 specific transactivation and apoptosis. (A) Mutant and wild-type
p53 expression vectors were cotransfected into H1299 cells with
luciferase constructs containing (p21p) or lacking (p21p1.1)
p53-responsive elements. PCR amplification of a known mutant p53
species (143-2M) containing a C170W mutation in exon 5 was performed in
parallel. Background transactivation of constructs lacking p53 response
elements was set to a value of 1. (B) Mutant and wild-type p53
expression vectors and RFP-expressing plasmids were cotransfected into
SAOS-2 cells by calcium phosphate precipitation (7). At
36 h posttransfection, apoptosis was measured by labeling the ends
of fragmented DNA with FITC. RFP-positive cells were gated the
percentage of cells dual positive for RFP and FITC are shown.
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We performed additional experiments to determine whether these specific
mutations affected the ability of p53 to induce apoptosis
in another
p53 null cell line, SAOS-2. Cells were cotransfected
with p53
expression constructs and RFP-expressing plasmids, and
the amount of
fragmented DNA indicative of apoptosis in RFP-positive
cells was
measured by FACS. As shown in Fig.
2B, the P203A, N239S,
and G244R
mutants were inhibited in their ability to induce apoptosis,
similar to
the known p53 mutant. In contrast, the E228G mutant
induced apoptosis
to levels similar to wild-type p53. Therefore,
three of these p53
mutations inhibit the ability of p53 to transactivate
the p21 promoter
and induce apoptosis in an in vitro transfection
system.
Wild-type and mutant p53 protein is expressed in tumors from Tax
transgenic mice.
We analyzed protein levels of p53 in tumors and
tumor-derived LGL cell lines from Tax transgenic mice by Western blot
analysis (Fig. 3). Cell lysates were
immunoprecipitated and immunoblotted with conformation-dependent
monoclonal antibodies which recognize either wild-type p53 (upper
panel) or mutant p53 (middle panel) or monoclonal antibodies against
HTLV-1 Tax (lower panel). Most point mutations in p53 dramatically
disrupt its secondary structure, allowing for recognition by
conformation-dependent antibodies (8). As shown in Fig. 3,
both wild-type and mutant p53 are expressed in tumors from Tax
transgenic mice. Tax expression appears to be restricted to primary
tail and ear tumors and absent in spleens (lanes 6 to 8). We have
previously shown that the F8 and SC tumor-derived cell lines expressed
Tax upon initial isolation; however, Tax expression was undetectable
once cells acquired IL-2 independence (15; Fig. 3, lanes 4 and 5). These data suggest an inverse correlation between frequency of
p53 mutation or tumor progression and Tax expression.
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FIG. 3.
Expression of wild-type and mutant p53 in tumors from
Tax transgenic mice. Cell lysates from tumor-derived cell lines (lanes
4 and 5) and fresh tumors from Tax transgenic mice (lanes 6 to 8) were
immunoprecipitated (IP) and immunoblotted with conformation-dependent
antibodies specific for wild-type p53 (top), mutant p53 (middle), or
HTLV-1 Tax (bottom). Wild-type p53-containing, HTLV-1-transformed T
cells (MT2), mutant p53-containing cells (143-2M), and normal mouse
splenic tissue (NMS) were utilized as controls. The upper band in each
panel represents mouse heavy-chain immunoglobulin (Ig) in each
sample.
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Tax-induced tumors are resistant to apoptosis.
To determine
the functional status of p53 in fresh tumors and tumor-derived cell
lines, we measured their sensitivity to irradiation-induced apoptosis
(Fig. 4). The levels of annexin V, an
early marker of apoptosis, were measured 5 h after mock or
-irradiation treatment. Nonirradiated and irradiated controls
exhibited between 6 and 25% and 89 and 72% annexin V-positive cells,
respectively. As shown in Fig. 4A, the F8 and SC tumor-derived cell
lines are completely resistant to apoptosis, similar to
HTLV-1-transformed MT2 cells, which are known to contain inactive p53
(34). Similarly, spleen and tail tumor cells from Tax
transgenic mice are also resistant to irradiation-induced apoptosis
(Fig. 4B), suggesting that p53 is functionally inhibited, whether by
mutation or an alternative mechanism. It was determined by scatter plot
analysis of tumor cells that the apoptosis-resistant cells consist
primarily of the larger, more numerous cells that are present in spleen
and tumor tissue from Tax transgenic mice and absent in normal mouse spleens (Fig. 4B, left column). These cells are FcIIIR positive, a
marker for the LGL cells that make up tumors in Tax transgenic mice
(reference 15 and data not shown).
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FIG. 4.
Tumors from Tax transgenic mice are resistant to
irradiation-induced apoptosis. Tumor-derived cell lines (F8 and SC) (A)
and fresh tumor cells from Tax transgenic mice (B) were either mock
treated (middle column) or exposed to 2,000 rads of -irradiation
(right column). Five hours later, cells were stained with
FITC-conjugated antibodies to annexin V to measure apoptosis. A
wild-type p53-containing cell line (204-3-1) and normal mouse
splenocytes (Ctrl Spleen) were used as positive controls. The
apoptosis-resistant cells consist of the larger, more numerous cells
present in spleen and tumor tissue from Tax transgenic mice and absent
in normal mouse spleens (compare scatter plots; left).
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p53 is transcriptionally active in Tax-induced tumors.
To test
the ability of p53 to transactivate downstream genes, total cellular
RNA was also isolated from nonirradiated and irradiated tumor cells at
2 h postirradiation. RT-PCRs were carried out to detect levels of
p21, bax, mdm2, and p53 mRNA (Fig. 5). Levels of GAPDH were normalized in order to quantitate the fold activations of p21, bax, mdm2, and p53 transcripts following
irradiation (Table 2). As expected,
upregulation of all transcripts ranged from 3- to 10-fold in cells
containing wild-type p53 (Fig. 5, lanes 1 and 2 and 11 and 12; Table 2)
and was not observed in cells which express either no p53 or mutant p53
(Fig. 5, lanes 3 to 6; Table 2) following -irradiation. Upregulation
of all transcripts was also observed in the tumor-derived F8 and SC
cell lines (Fig. 5, lanes 7 to 10; Table 2) as well as tumors (Fig. 5,
lanes 13 to 16; Table 2) from Tax transgenic mice. It is difficult to
accurately assess transcriptional activation in Tax spleen cells due to
the presence of normal, nonmalignant cells; however, p53-mediated
transactivation did not appear to be lower than that in control spleen
cells (three- to fourfold) except in the case of p21 (Table 2). These
results were surprising, given the fact that tumors were resistant to
apoptosis, and suggest that the presence of p53 mutations in tumors
does not affect the normal transactivation function of p53 following
-irradiation.
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FIG. 5.
p53 transactivation activity is functional in
Tax-induced tumors and tumor-derived cell lines. Total cellular RNA was
isolated from nonirradiated ( ) and irradiated (IR) (+) cells at 2 h
postirradiation. RT-PCRs were performed using primers specific for p21,
bax, mdm2, and p53 mRNA. Levels of GAPDH were measured in parallel to
demonstrate that equivalent amounts of RT product were used in each
reaction. Cells containing wild-type p53 (204-3-1), mutant p53
(143-2M), and no p53 (L1-2) were utilized as controls to measure p53
transactivation activity.
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Tumorigenesis in p53+/ Tax+ mice
progeny.
To determine if the loss of functional p53 contributes to
tumor formation in vivo, we bred Tax transgenic mice with homozygous p53 mutant mice (18). F1 progeny
(p53+/ Tax+) were then mated for production
of F2 progeny. Mice with homozygous p53 mutations develop a
variety of malignancies and die as early as 6 months of age. Tumors
arising in p53/ mice include sarcomas and CD4+ CD8+
lymphomas, which can be distinguished from Tax transgenic LGL tumors
(18).
By histological analysis, we found that p53
/
Tax
+ mice develop tumors at the same rate as, and which are
identical in histology
to those of, p53
/ mice,
particularly large-cell non-Hodgkin's lymphomas in the
spleen and
liver, distinct from Tax-induced tumors (data not shown).
None of the
p53
/ Tax
+ mice developed Tax-induced LGL
tumors, and the mice died before
the normal onset of Tax tumors; thus,
we were unable to use these
mice in our analysis (Fig.
6A). However, we would have expected
to
see development of Tax tumors in some of the mice before death
if p53
inactivation was a critical obstacle to overcome for tumor
development.
Instead, we compared the rate of initial tumor formation
in
p53
+/ Tax
+ mice to that of p53
+/+
Tax
+ mice. Tax-induced peripheral tumors formed in 100% of
these mice.
In agreement with in vitro p53 transactivation experiments,
we
observed only a slight acceleration in tumor formation, which
was
not statistically significant (
P < 0.2), in
p53
+/ Tax
+ mice compared to that in mice
transgenic for Tax alone. This
would suggest that Tax-induced
inactivation of p53 is not required
for initial tumor development (Fig.
6A).
View larger version (16K):
[in this window]
[in a new window]
|
FIG. 6.
Tumor initiation and progression in progeny from
p53+/ Tax+ transgenic mice. Tax transgenic
mice (solid lines) were mated with p53/ mice, and
F1 progeny (p53+/ Tax+) were
mated for production of F2 progeny. (A) The percent
tumor-free survival is plotted as a function of age. Animals were
monitored weekly for tumor formation, morbidity, or spontaneous death
over a period of 9 months. Except for p53/
Tax+ (n = 14) and p53/
(n = 5) mice, at least 20 mice were used for each
comparison. The percent morbidity-free (development of fewer than four
visible tumors; n < 3) survival (B) and the percentage
of mortality-free mice (C) were measured from the time of initial tumor
formation.
|
|
When we then monitored tumor progression beginning from the time of
initial tumor formation, we observed that mice heterozygous
for
p53 developed peripheral LGL tumors at four or more sites
(
P < 0.03) (Fig.
6B) and died significantly earlier
(
P < 0.01)
(Fig.
6C) than mice containing wild-type
p53 alleles. These results,
taken together, indicate that
abrogation of p53 activity by Tax
is not required for initial tumor
formation. Rather, Tax may specifically
inhibit other components of the
p53 pathway to induce cellular
resistance to apoptosis. Furthermore,
loss of p53 function, whether
by mutation or another method, likely
contributes to rapid dissemination
and increased mortality of mice once
tumors are
established.
| |
DISCUSSION |
There are considerable data suggesting that the HTLV-1 Tax protein
induces tumorigenesis by deregulation and functional inhibition of
cellular proteins, including components of the p53/Rb pathway. We have
utilized a Tax transgenic mouse model to determine the contribution of
p53 inactivation to Tax-induced tumorigenesis. Our results suggest that
Tax expression in an in vivo mouse model of tumorigenesis does not
affect the transactivation function of p53 and that p53 inactivation,
whether by mutation or other method, does not contribute to accelerated
tumor formation. These findings differ from those of Pise-Masison et
al., which demonstrate inhibition of p53-mediated transcriptional
activation and apoptosis in HTLV-1-immortalized cell lines (31,
32). The differences may reflect the two distinct model systems
used: one utilizes a mouse model of Tax expression and the other
utilizes HTLV-1-immortalized human cells. We have not looked at altered
phosphorylation of p53 as a mechanism of Tax inhibition in our system,
given the fact that p53 appears to function normally when activated by
-irradiation. Thus, we cannot rule out this possibility, especially
since -irradiation induces a series of downstream phosphorylation
events which may override any inhibition induced by Tax
(12).
By PCR-SSCP analysis, we identified specific mutations in the critical
DNA binding domain of p53 in tumors from Tax transgenic mice. We initially identified p53 mutations in 43% of
primary, peripheral tumors and 91% of sites of organ infiltration.
Four specific mutations in exons 6 and 7 of p53 were further
characterized since their high frequency of occurrence indicated that
they were not PCR artifacts. These mutations were confirmed by
restriction enzyme digestion of genomic DNA; moreover, mutant p53
protein expression in tumors and tumor-derived cell lines was
identified by Western blot analysis. Three of these mutations, although
inhibitory in an in vitro transfection system, apparently are not
predominant enough in tumors to abrogate p53 transactivation of
downstream p53 responsive genes following -irradiation. However, it
is possible that these mutations may be inhibitory under more
physiologic conditions of stress.
Our results are similar to those utilizing Abelson MLV-transformed
pre-B cells, in which inhibitory mutations clustered within the p53
core domain were generated late in transformation and appeared not to
be required for initial transformation. However, unlike the Tax-induced
tumors in our system, MLV-transformed cells predominantly expressed
mutant p53, which is unable to activate p21 transcription or
induce apoptosis following irradiation (43). In our
system, tissues containing disseminated tumor cells also harbored large
numbers of nonmalignant cells, which made it difficult to measure the
percentage of tumor cells containing specific p53 mutations. The
presence of p53 mutations in the IL-2-independent tumor-derived cell
lines from Tax transgenic mice supports the idea that late-stage
genetic mutations in p53 may allow cells to grow without exogenous
cytokines. However, if these mutations provide a growth advantage for
tumor cells, it is expected that organ-infiltrating tumor cells would
be clonal and contain predominantly mutant p53. This was not
observed when biological clones were cultured from tumors, suggesting
that these mutations do not need to be selected for tumor outgrowth in
vitro. An alternative explanation is supported by the finding that Tax
inhibits nucleotide excision repair, presumably through increased
proliferating cell nuclear antigen expression (21, 35).
This may predispose cells to accumulation of DNA damage and spontaneous
mutation, an event that has been attributed to Tax expression
(28).
Despite the fact that p53 transactivation activity is normal, the
apoptotic pathway appears to be inactive in tumors and tumor-derived cell lines from Tax transgenic mice, based upon their resistance to
-irradiation. Additionally, only the larger tumor cells present in
spleen and tail tumors were resistant to apoptosis. The smaller lymphoid cells were sensitive to apoptosis, similar to cells present in
normal control mouse spleens. In support of our findings, resistance to
Fas-mediated apoptosis in spleen cells has also been associated with
escape of autoreactive T cells and development of autoimmune disease in
HTLV-1 transgenic mice (22).
In addition to transcription-dependent p53-mediated apoptosis, a
transcription independent pathway of apoptosis has been described. This
pathway is thought to involve the proline-rich region of p53, located
between the central DNA binding domain and the 5' transactivation
domain. This region mediates binding of p53 to proteins containing SH3
domains and is thought to be involved in induction of apoptosis, yet
dispensable for p53-mediated transactivation (24, 36).
This pathway, largely bax independent, is suggested to involve
additional signals or cofactors necessary for apoptosis or suppression
of a survival factor needed to inhibit the actions of bax
(36). We have not ruled out the possibility that mutations in this region of p53 may be present in Tax-induced tumors or that Tax
disrupts protein-protein interactions involving this region,
independent of mutation.
Another possibility is that Tax inhibits downstream effectors of p53
necessary for apoptosis. For instance, resistance to apoptosis induced
by the Epstein-Barr virus LMP-1 protein is associated with expression
of the anti-apoptotic bcl-2 and A20 proteins, which are regulated by
NF-B activation. In fact, it has been suggested that a critical
balance between pro- and antiapoptotic bcl-2 family members regulates
apoptosis (40). Along these lines, studies have shown that
Tax can transrepress expression of the apoptosis-promoting protein bax
and can transactivate expression of the antiapoptotic protein bcl-xl,
most likely through the NF-B elements in the bcl-xl promoter. This
action is associated with development of IL-2 independence in CTLL-2
cells (3, 17, 44). To our knowledge, Tax-mediated
inhibition of other essential downstream components of p53-mediated
apoptosis has not been researched. Herpes simplex virus-1, for example,
has been shown to specifically inhibit both caspase-8 and caspase-3
activity following induction of apoptosis (19).
The finding that tumor formation in p53+/
Tax+ mice was not significantly accelerated compared to
that of p53+/+ Tax+ mice supports our in vitro
p53 transactivation data. p53 functions primarily as a tetramer, and it
has been shown that a mere reduction in p53 levels may promote
tumorigenesis; therefore, an increased rate of Tax-induced tumor
formation in p53 heterozygous mice would have been observed if p53
inactivation contributed to tumor formation (46). In fact,
a recent study by Li et al. demonstrates that p53+/ mice
transgenic for HPV E6 and E7 develop a novel lymphomagenesis, which is
not observed in p53+/+ E6 and E7 or p53+/
mice, at 3 to 6 months of age. This suggests that p53 inactivation from
degradation by HPV E6 and E7 is important for tumor development in
these animals (25). Tumors developing in
p53/ Tax+ mice are identical to those of
p53/ mice and arise earlier than tumors induced by Tax
alone (3 to 5 months versus 6 to 9 months). Again, we would expect to
see development of Tax-induced peripheral tumors sometime before death of the mice if p53 inactivation was an obstacle to overcome for tumor
formation. This is in contrast to studies involving infection of
p53-deficient mice with Abelson MLV. These mice demonstrated a
shortened latency period before tumor formation, suggesting that p53
inactivation is important for tumor development induced by this virus
(45). Similarly, using a Wnt-1 mouse mammary tumor model,
Jones et al. have shown that p53 deficiency contributes to accelerated
tumor development (20).
When we then monitored tumor progression in p53+/
Tax+ and p53+/+ Tax+ mice,
beginning from the time of initial tumor formation, we observed
formation of multiple tumors (n > 3) and accelerated mortality in Tax transgenic mice heterozygous for p53. The
tumors were identical to those induced by Tax alone and distinct from late-stage tumors described for p53+/ mice
(18). This suggests that, once tumors are established, p53
inactivation allows for a more aggressive disease course, resulting in
rapid dissemination and death. Our results are supported by the
observation that, since p53 can be induced by hypoxia, the presence of
a rich blood supply early in tumor development (i.e.,
leukemia/lymphoma) results in late selection for p53 inactivation in
tumors (24). Additionally, a study of erythroleukemias
induced by Friend MLV suggests that p53 inactivation does not directly immortalize cells but promotes accumulation of mutations that lead to
accelerated tumor progression in vivo (48). Taken
together, these results suggests that p53 inactivation by Tax, whether
by mutation or another mechanism of inhibition, is not critical for initial tumor formation. Rather, p53 inactivation likely occurs late in
tumorigenesis and may be responsible for rapid dissemination and the
extremely aggressive and fatal course of ATLL.
We propose that Tax expression in our mouse model induces uncontrolled
entry into the cell cycle (29, 37, 39, 42) and inhibits
apoptosis induced by DNA damage (32, 44) while disrupting
DNA repair systems (21, 35). Our RT-PCR results suggest
that this occurs either independent of or downstream of p53. After
cells enter a transformed state, p53 is likely inactivated, either by
genetic damage or a more direct mechanism, leading to rapid tumor
dissemination and death as demonstrated in p53+/
Tax+ mice. Future studies will utilize this
transgenic-mouse model to identify the initial events in HTLV-1
Tax-mediated tumorigenesis, specifically with regard to inhibition of
the apoptotic pathway.
| |
ACKNOWLEDGMENTS |
We thank Naomi Rosenberg, Doug Dean, and Rainer Brachmann for
reagents and technical support.
This work was supported by National Institutes of Health grants
CA-63417 and RR-14324, a National Heart Lung and Blood Institute National Research Service Award, and a Leukemia and Lymphoma Society fellowship.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Box 8069, Washington University, 660 South Euclid Ave., St. Louis, MO 63110. Phone: (314) 362-8836. Fax: (314) 747-2797. E-mail:
lratner{at}imgate.wustl.edu.
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Journal of Virology, March 2001, p. 2185-2193, Vol. 75, No. 5
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.5.2185-2193.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
