Previous Article | Next Article 
Journal of Virology, January 2000, p. 883-891, Vol. 74, No. 2
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
LMP1 of Epstein-Barr Virus Induces Proliferation of
Primary Mouse Embryonic Fibroblasts and Cooperatively Transforms the
Cells with a p16-Insensitive CDK4 Oncogene
Xinhai
Yang,1
Jonathan S. T.
Sham,2
M.
H.
Ng,1
Sai-Wah
Tsao,3
Dekai
Zhang,3
Scott W.
Lowe,4 and
Liang
Cao1,*
Department of
Microbiology,1 Department of Radiation
Oncology,2 and Department of
Anatomy,3 The University of Hong Kong, Hong
Kong, People's Republic of China, and Cold Spring Harbor
Laboratory, Cold Spring Harbor, New York4
Received 26 July 1999/Accepted 7 October 1999
 |
ABSTRACT |
The latent membrane protein LMP1 of Epstein-Barr virus (EBV) is
often present in EBV-associated malignancies including nasopharyngeal carcinoma and Hodgkin's lymphoma. Previous work demonstrates that the
LMP1 gene of EBV is sufficient to transform certain established rodent
fibroblast cell lines and to induce the tumorigenicity of some human
epithelial cell lines. In addition, LMP1 plays pleiotropic roles in
cell growth arrest, differentiation, and apoptosis, depending on the
background of the target cells. To examine the roles of LMP1 in cell
proliferation and growth regulation in primary culture cells, we
constructed a recombinant retrovirus containing an LMP1 gene. With this
retrovirus, LMP1 was shown to stimulate the proliferation of primary
mouse embryonic fibroblasts (MEF cells). It has a mitogenic activity
for MEF cells, as demonstrated by an immediate induction of cell
doubling time. In addition, it significantly extends the passage number
of MEF cells to more than 30 after retroviral infection, compared with
less than 5 for uninfected MEF cells. Furthermore, LMP1 cooperates with
a p16-insensitive CDK4R24C oncogene in
transforming MEF cells. Our results provide the first evidence of the
abilities of the LMP1 gene, acting alone, to effectively induce the
proliferation of primary MEF cells and of its cooperativity with
another cellular oncogene in transforming primary cells.
| |
INTRODUCTION |
Epstein-Barr virus (EBV) is a human
gammaherpesvirus commonly carried in the majority of the human
population. It is the causative agent for proliferative diseases such
as infectious mononucleosis and oral hairy leukoplakia in AIDS
patients. It is also implicated in a variety of human malignancies that
include Burkitt's lymphoma, nasopharyngeal carcinoma, Hodgkin's
lymphoma, nasal T-cell lymphoma, and immunoblastic lymphomas in
posttransplant and AIDS patients (39). The virus often
adopts latent forms in EBV-associated cancers. In nasopharyngeal
carcinoma and Hodgkin's lymphoma, type II latency gene expression was
observed. During this type II latency, only three viral proteins are
routinely detected: EBV nuclear antigen 1 (EBNA1) and two latent
membrane proteins, LMP1 and LMP2. Among the three EBV genes, the LMP1
gene is the only one implicated in cell immortalization and
transformation. It is one of the viral genes required for B-cell
immortalization, together with the EBNA2, EBNA3a, and EBNA3c genes
(8, 15, 22, 23, 48). In addition, LMP1 has been shown to
induce the transformation of certain established rodent fibroblast cell
lines, including Rat-1 and BALB/c 3T3 (2, 33, 49).
Furthermore, LMP1 induces the morphological transformation of the
RHEK-1 cell line (12) and the tumorigenicity of epithelial cell lines in severe combined immunodeficient mice (18, 36).
Although EBV is an important oncogenic virus in human, the LMP1
genes appeared to act differently from oncogenic genes of other DNA
oncogenic viruses, including simian virus 40 (SV40) large T antigen,
adenovirus E1A and E1B, and human papillomavirus (HPV) E6 and E7. There
is little evidence suggesting that the LMP1 gene can function similarly
to these viral oncogenes or even a cellular oncogene such as
ras or myc. Though LMP1 transforms several
immortalized rodent fibroblast cell lines and participates in B-cell
immortalization, a single LMP1 gene has not been shown to induce
continuous proliferation of any primary cell culture. Similarly,
although it cooperates with a number of EBV genes in inducing B-cell
proliferation, there is no report on the cooperativity of the LMP1 gene
with another cellular oncogene in transforming primary cells.
Protein sequence analysis of LMP1 revealed at least three domains: an
amino-terminal cytoplasmic domain of 20 amino acid residues, a
six-transmembrane domain of 185 amino acid residues, and a
carboxy-terminal cytoplasmic domain of 200 amino acid residues
(24). The six-transmembrane domain was shown to be required
to form cytoplasmic membrane patches. The oligomerization of LMP1 in
the cytoplasmic membrane may mimic that of other membrane receptor
molecules induced by ligand-receptor interactions, resulting in
constitutive activation of the LMP1 signaling pathway (14).
The C-terminal cytoplasmic region was shown to interact with two
families of proteins, TRAF (tumor necrosis factor [TNF]
receptor-associated factor) and TRADD (TNF receptor-associated death
domain), through two distinct domains (21, 34). These two
domains participate in NF-
B activation (19, 32) and in the transformation of primary B cells with other EBV genes
(20, 21). Other recent studies suggest that LMP1 can also
induce the activation of c-Jun N-terminal kinase (JNK), resulting in the induction of AP1 activity of the transfected cells (11, 25). However, JNK and AP1 activations were also reported for the
TNF signaling pathway responsible for the suppression of apoptosis (1). The roles of JNK and AP1 activation in LMP1-mediated
cellular proliferation and transformation remain to be elucidated.
To understand the roles of LMP1 in cell proliferation and growth
regulation in primary culture cells, we used a retrovirus to deliver
LMP1 in the primary mouse embryonic fibroblast (MEF cell) model system.
This approach allowed the integration and stable expression of LMP1
gene in the target cells at a high efficiency, thus permitting
continuous analysis of the effect of LMP1 in primary culture cells in
the absence of any drug selection. The results of our study indicate
that LMP1 alone is sufficient to induce the proliferation of MEF cells.
It has a mitogenic activity for MEF cells and is capable of
significantly extending their passage numbers in culture. Furthermore,
although LMP1 fails to cooperate with the ras oncogene to
transform MEF cells, it cooperates with the
CDK4R24C oncogene (46) to do so.
| |
MATERIALS AND METHODS |
Retroviral plasmids.
A 1.95-kb fragment containing a
full-length LMP1 gene (pLMP1 [6]) was removed and
inserted into the BamHI site of pcDNA3 to give pcDNA3-LMP1.
The LMP1 fragment then was isolated with HindIII and
EcoRV digests and cloned into HindIII and
ClaI sites of the retroviral vector pLNSX (31) to
generate pLNSX-LMP1. Other retroviral plasmids used in the study are
pBabe-Ras with an active form of human H-rasV12
cDNA (46) and pWZL-R24C with a p16-insensitive
CDK4R24C oncogene (46).
Cell culture and preparation of MEF cells.
Cell culture was
carried out in Dulbecco modified Eagle medium supplemented with 10%
fetal bovine serum (GIBCO). PA317 and Bosc23 (American Type Culture
Collection) are amphotropic and ecotropic retrovirus packaging
cell lines, respectively. To produce MEF cells for the experiment, day
14 embryos were obtained from pregnant BALB/c mice. After removal of
the head and red organs, the torso was minced and digested with 0.1%
trypsin and 0.1% collagenase for 30 min at 37°C. The cells were
seeded onto 10-cm cell culture dishes and split once at 1:4 before
being frozen. For retroviral infections, the cells were thawed and
split once more prior to infection.
Gene transfer mediated by retrovirus.
To obtain
retroviruses, the retroviral plasmids were transfected into the
ecotropic retrovirus packaging cell line Bosc23 with Lipofectin
(GIBCO). After 15 h of incubation at 37°C, cells were placed in
fresh medium and further incubated for 48 h. The virus-containing
supernatants were collected at this time and again 12 h later.
After filtering through 0.45-µm-pore-size filters (Millipore), the
viral stocks were supplemented with Polybrene (8 µg/ml; Sigma). The
viruses were then used to infect the amphotrophic viral packaging cell
line PA317. After 24 h of infection, the infected PA317 cells were
selected with the appropriate drug: puromycin (2 µg/ml) for pBabe,
geneticin (500 µg/ml) for pLNSX, or hygromycin (200 µg/ml) for
pWZL. Two or three weeks later, the resistant cells were collected and
expanded as the virus-producing cell lines. To produce the viral stock,
fresh medium was added to the virus-producing cells and incubated for
24 to 48 h. The virus-containing supernatants were collected and
filtered as before. After supplementation with Polybrene (4 µg/ml),
the supernatants were used fresh as viral stocks or aliquoted and
stored at 
80°C. Characterization and titration of the viruses were
carried out with appropriate drug selections, immunofluorescence, and
Western blotting with appropriate antibodies. Most of the viral stocks have titers ranging from 1 × 105/ml to 4 × 105/ml. In a typical experiment, Rat-2 or REF52 cells
(5 × 105 per well) were seeded into six-well plates
the day prior to infection. A fixed volume of a viral stock was used to
infect the target cells for 48 h. LMP1-expressing virus-infected
(MEF-LMP1) cells were trypsinized and seeded onto eight-well slides for
immunofluorescence analysis by using monoclonal antibody S12, specific
for LMP1, to determine the viral titer. Similar results were obtained
with a number of mouse fibroblast and human epithelial cell lines. For
all subsequent experiments, MEF cells were plated at 2 × 105 cells per well in six-well plates and incubated with an
appropriate viral stock overnight. The culture medium was then replaced
with another viral stock in the coinfection studies and incubated for another 8 h. The infected MEF cells, regarded as passage 1 (P1), were subcultured in normal medium without drug selection and split 1:4
when they reached confluence.
Cell growth analysis.
For cell growth curves, 2,000 cells
were seeded per well into 24-well microtiter plates 24 h after
viral infections. At the indicated time points, the cells were removed
with trypsin digestion and the number of cells was counted. The
experiment was done in triplicate to determine the number of cells
at each time point and standard deviation. This experiment was
reproduced twice.
Soft agar assay.
For soft agar assay, infected MEF cells at
P3 or P6 were seeded into semisolid agarose medium (Dulbecco modified
Eagle medium supplemented with 10% fetal calf serum) and
low-melting-point agarose (base layer, 0.6%; upper layer, 0.35%) at a
density of 4 × 103 cells per well in six-well plates
(Nunc). The cells were fed each week with several drops of fresh medium
placed directly onto the surface of the upper layer. After 2 to 3 weeks of incubation at 37°C, foci were viewed and counted.
Photographs were taken under a microscope for analysis of
representative colonies or with a regular camera after staining of the
dishes with Giemsa and destaining with 50% ethanol in
phosphate-buffered saline.
Immunoblot analysis.
Cells were collected and then washed
with ice-cold phosphate-buffered saline and lysed in NP-40 lysis buffer
(5). Cell lysates were made and analyzed for protein
concentration by the Bradford assay (Bio-Rad). Then 100-µg aliquots
of protein lysates were mixed with sample buffer and boiled for 5 min;
they were then separated on sodium dodecyl sulfate-10% polyacrylamide
gels and transferred to nitrocellulose membranes by electroblotting. Western blotting with a monoclonal antibody against LMP1 (S12) or an
antibody against CDK4 (H-303; Santa Cruz) was followed by detection
with an ECL (enhanced chemiluminescence) detection kit (Amersham).
Telomerase activity assay.
Telomerase activity was
determined by TRAP assay (7). To minimize the effect of
telomerase inhibitors that may have been present in the sample
extract, each specimen was assayed at two concentrations (1-fold and
10-fold dilutions). For an RNase control, the lysate was preincubated
with 0.5 µg of DNase-free RNase at room temperature for 15 min before
the TRAP assay.
| |
RESULTS |
The LMP1 gene is effectively introduced into MEF cells via
retrovirus.
To effectively introduce LMP1 into primary culture
fibroblasts and monitor the cells continuously without the selective
pressure of drugs, an LMP1-expressing retrovirus (v-LMP1) was generated and evaluated in Rat-2 cells by immunofluorescence and immunoblotting using a specific mouse monoclonal antibody against LMP1, S12
(30) or CS1-4 (42). We estimated that our
optimized infection condition routinely resulted in infection of about
50% of the cells. Further study revealed that the v-LMP1 stocks were
also capable of effectively infecting mouse fibroblast, human diploid
fibroblast (IMR90), and human epithelial cell lines (data not shown).
To analyze the effects of LMP1 on primary MEF cells, v-LMP1 was then
used to infect the cells. These P1 cells were then cultured in medium
without drug selection and split 1:4 upon reaching confluence. After
two additional passages, the lysates of cells at P3 were analyzed by
Western blotting and immunofluorescence with LMP1 antibody S12. Western
blot results revealed two prominent immunoreactive bands with molecular
masses of 60 and 43 kDa that were specifically detected from the
lysates of v-LMP1-infected MEF cells, identical to those from the
lysate of EBV-positive B95-8 cells (42) (Fig. 1). The Western blot result is consistent
with previous findings for LMP1 protein. The 60-kDa band is the
full-length LMP1, and the smaller 43-kDa band is likely a breakdown
product. Both bands are absent in the EBV-negative lymphoblastic
leukemia cell line MOLT-4 or in MEF cells infected with a vector
retrovirus (v-LNSX). LMP1 proteins in v-LMP1-infected MEF cells are
primarily full length. The stability of LMP1 appears to be a feature of
the LMP1 gene used in the retrovirus and independent of the types of
cells used for the infections (data not shown).
View larger version (54K):
[in this window]
[in a new window]
|
FIG. 1.
Western blot analysis of LMP1 in MEF cells after
infection with v-LMP1. MEF cells were infected with either v-LNSX
(MEF-Vector) or v-LMP1 (MEF-LMP1) and passaged twice before collected
for analysis (P3). B95-8 is an EBV-positive marmoset B-lymphocyte cell
line that expresses LMP1, and MOLT-4 is an EBV-negative lymphoblastic
leukemia cell line. Cell lysates were made, and 100 µg of protein was
loaded in each lane for Western blot analysis unless otherwise
indicated. To compare the relative levels of LMP1 in MEF-LMP1 and B95-8
cells, two- and fourfold dilutions of both lysates were made and
analyzed. A mouse monoclonal antibody against LMP1, S12, was used for
the immunoblot.
|
|
The retrovirus provided a good system for introducing LMP1 into MEF
cells. At P3, over 90% of v-LMP1-infected MEF cells expressed
LMP1,
seen in the cytoplasm or on the cell surface in small aggregations,
whereas the v-LNSX-infected MEF cells were negative in the assay
(Fig.
2A and B). The total amount of LMP1 in
v-LMP1-infected MEF
cells was substantially higher than that in B95-8
cells, as indicated
by their relative intensities in Western blot
analysis of sequentially
diluted lysates (Fig.
1). This difference may
be partly due to
the observation that the majority of v-LMP1-infected
MEF cells
expressed LMP1 at P3, whereas a significantly smaller
percentage
of our cultured B95-8 cells were positive for LMP1 in the
immunofluorescence
assay (Fig.
2C). The negative control MOLT-4 cells
were negative
for LMP1 (Fig.
2D).
View larger version (88K):
[in this window]
[in a new window]
|
FIG. 2.
Immunofluorescence analysis of v-LMP1-infected MEF
cells. Cells were immunostained with LMP1 antibody S12 and
counterstained with propidium iodide for nuclei. (A) MEF cells infected
with v-LMP1 and subcultured twice (P3) before staining with S12
antibody for LMP1 expression. The green sparkles represent LMP1
proteins localized in cytoplasm or on cytoplasmic membrane. (B) MEF
cells infected with control virus v-LNSX (P3). (C) B95-8 cells stained
with S12 as the positive control. About 5 to 10% of our cultured cells
were positive for LMP1. The positive signal is yellow due to the
combined effect of green and red fluorescence. (D) MOLT-4 cells stained
with S12 as the negative control.
|
|
The level of LMP1 expressed in v-LMP1-infected MEF cells was stable for
up to 30 passages after infection in the absence of
any drug selection,
as indicated by Western blot results for LMP1
(Fig.
3). In addition, the immunofluorescence
of MEF-LMP1 cells
at P24 revealed that virtually all cells were
positive for LMP1
(data not shown). Thus, this retroviral system
provided an effective
way to stably introduce and express LMP1 in
primary fibroblasts.
The result further suggested the absence of
cellular toxicity
of LMP in primary MEF cells, as it was expressed in
more than
90% of the cells starting from P3 (Fig.
2A), and the level
of
expression was stable throughout the course of the experiment
(Fig.
3). In contrast, there appeared to be a growth advantage
for
LMP1-expressing MEF cells since only about 50% of the infected
cells
expressed LMP1 immediately following v-LMP1 infection, at
the end of
P1. Two passages later (P3), 90% of the MEF were positive
for LMP1 in
the absence of drug selection. Interestingly, expression
of LMP1 was
correlated with increasing passage numbers of MEF
cells, which normally
can be passaged only a few times in culture
before reaching senescence.
View larger version (52K):
[in this window]
[in a new window]
|
FIG. 3.
The expression of LMP1 in v-LMP1-infected MEF cells is
stable in the absence of drug selection. The cell lysates were obtained
from MEF cells infected with v-LNSX (MEF-Vector) or v-LMP1 (MEF-LMP1)
at P3, P11, and P30 following infection with v-LMP; 100 µg of protein
was loaded in each lane for Western blot analysis with antibody S12.
B95-8 is an EVB-positive cell line, and MOLT-4 is an EBV-negative cell
line. Western blotting against  -actin was used as the loading
control.
|
|
LMP1 induces the proliferation of MEF cells associated with
extended passage numbers.
The effects of LMP1 on primary
fibroblast cells were studied by infecting MEF cells with v-LMP1 or
with v-LNSX as a negative control. The virus-infected cells were
subsequently pooled and repeatedly subcultured whenever they reached
confluence, which usually took about 1 week at early passages.
Immediately after infection with retroviruses, all cell cultures
presented the typical morphology of primary fibroblasts (Fig.
4A). The v-LNSX-infected cells had a low
plating efficiency and grew slower with each additional passage,
similar to the uninfected MEF cells. The cells gradually adopted a
flatter and enlarged shape suggestive of an aging process. By P4 (12 population doublings), most v-LNSX-infected cells reached a senescence
stage and could not be passaged further (Fig. 4B). The v-LMP1-infected
MEF cells, however, behaved very differently from the v-LNSX negative
control. Although v-LMP1-infected cells exhibited a morphology and
growth rate similar to those of the v-LNSX control during P1, they
displayed significant differences in both cellular morphology and
proliferating ability at P2 and P3. The cells exhibited a higher
plating efficiency and more vigorous growth with an apparently higher
growth rate. In addition, the morphology of the cells changed to
smaller and a long spindle shape, and the population gradually became
relatively homogeneous, as indicated by a photo of MEF at P10 (Fig.
4C). Furthermore, it was clear that MEF-LMP1 cells can be passaged much
further than MEF-LNSX cells. While uninfected MEF cells and MEF-LNSX
cells were passaged fewer than five times, MEF-LMP1 cells had been
subcultured for more than 30 passages and apparently could be readily
passaged further. The result that LMP1 induced the proliferation of MEF cells was reproducible in a total of four independent experiments using
MEF cells from two sets of mouse embryos over the course of 1 year. While the v-LNSX-infected MEF cells reached senescence before P6
in all experiments, the v-LMP1-infected MEF cells have been
consistently passaged further. At present they have undergone 35, 22, 13, and 12 passages in these four experiments, and all maintain
vigorous growth. Thus, the LMP1 gene alone is sufficient to induce the
extended proliferation of MEF cells by significantly increase their
passage numbers in vitro.
View larger version (181K):
[in this window]
[in a new window]
|
FIG. 4.
LMP1 extends the passage number of MEF cells and induces
a morphological transformation of the cells in cooperation with
CDK4R24C. (A) P1 MEF cells infected with v-LNSX.
(B) P4 MEF cells infected with v-LNSX. Cells are flat and enlarged,
indicating that they are approaching senescence. This is the last
passage that can be routinely obtained with MEF-LNSX cells. (C) P10 MEF
cells infected with v-LMP1. Cells are smaller, with a long spindle
shape. They have a higher plating efficiency and grow continuously. (D)
P10 MEF cells coinfected with v-LMP1 and
v-H-rasV12. Their morphology and growth
properties are similar to those of v-LMP1-infected cells. (E) P4 MEF
infected with v-CDK4R24C. The cells were further
passaged once before they stopped dividing. (F) P10 MEF cells
coinfected with v-LMP1 and v-CDK4R24C. The cells
exhibit a transforming morphology characterized by smaller and shorter
cells with a high density. They are the most actively proliferating
cells.
|
|
LMP1 stimulates the growth rate of MEF cells.
It was apparent
that the v-LMP1-infected MEF cells grew faster than the v-LNSX-infected
cells starting from P2, one passage away from the initial infections.
To analyze the mitogenic effects of LMP1 on MEF cells, we examined the
growth rates of MEF cells infected with v-LMP1 or v-LNSX by plating out
the cells at the end of P1 into 24-well plates at a density of 2,000 cells per well. The cells were further incubated for growth analysis in a triplicate experiment in the absence of drug selection. At fixed time
intervals, the cells were harvested and cells per well were counted for
8 days since the MEF-LMP1 cells nearly reached confluence by day 8. The
results indicate that v-LMP1-infected cells grew substantially faster
than v-LNSX-infected MEF cells (Fig. 5). The LMP1-expressing cells have a doubling time of about 3 days, whereas
the vector control cells double every 4.5 days at this passage.
However, it should be noted that the growth of MEF cells in vitro is a
dynamic process, and cell growth became slower with each additional
passage as though the cells were going through a rapid aging process.
The results presented suggest that LMP1 has an immediate mitogenic
effect on MEF cells in addition to its ability to significantly extend
their passage numbers.
View larger version (16K):
[in this window]
[in a new window]
|
FIG. 5.
LMP1 increase the growth rate of MEF cells. MEF cells
were freshly infected with v-LNSX (diamonds) or v-LMP1 (squares). After
infection, the cells were removed from the plates with trypsin
digestion at the end of P1; approximately 2,000 cells were plated in
each well of 24-well plates in triplicate at day 0 and incubated
further at 37°C. At the indicated time points, the cells were removed
from the plates with trypsin and counted. The average numbers of cells
at each time point was determined, and their standard derivations were
obtained and plotted.
|
|
LMP1 cooperates with CDK4R24C in
transforming MEF cells.
Although LMP1 induces the extended
proliferation and increased growth rate of MEF cells, the MEF-LMP1
cells were not transformed even after 30 passages, as they preserved
contact inhibition for growth on plates and failed to grow in soft agar
(data not shown). In fact, most cellular and viral oncogenes are not
capable of transforming primary MEF cells alone, and the cooperative
transformation of primary murine fibroblast cells between oncogenes is
an important feature of them. However, little information is available
about the ability of LMP1 to cooperatively transform primary cells with any other cellular oncogene. Such cooperative transformation may be
important as an indication of the roles of LMP1 in a multistep process
of carcinogenesis, and it may provide a genetic model system with which
to delineate the mechanism or pathway involved in LMP1-mediated
transformation. To address the role of LMP1 in cooperatively
transforming primary rodent fibroblast cells, retroviruses containing
constitutive active H-rasV12
(v-H-rasV12 [46]) and
p16-insensitive CDK4R24C
(v-CDK4R24C [46]) genes were
used in the cotransformation assay. A previous experiment indicated
that LMP1 could mediate ERK1/2 activation in Rat-1 fibroblasts via a
Ras-dependent pathway (40). Activated Ras and ERK1/2 can
result in the up-regulation of cyclin D1 expression (28).
The second oncogene, CDK4R24C, was
originally identified in human melanomas with an arginine-to-cysteine exchange at residue 24 (51). This mutation prevents the
binding of CDK4 to its inhibitor p16INK4a. As a
result, CDK4R24C forms a complex with cyclin D1,
and the CDK4R24C-cyclin D1 complex is resistant
to the inhibition of p16INK4a in vivo
(3).
As indicated above, a single LMP1 gene did not induce cell
transformation. Similarly, the MEF cells coinfected with v-LMP1
and
v-H-
rasV12 (MEF-LMP1-Ras cells) also had an
extended passage number, although
they did not present any degree of
morphological transformation
at P10 in two experiments (Fig.
4D).
v-H-
rasV12 is functional since it transformed
both NIH 3T3 and Rat-1 fibroblasts
(data not shown), and we have found
that it induces an immediate
premature senescence of MEF cells
(reference
46 and data not
shown). The presence of
v-H-
rasV12 in MEF-LMP1-Ras cells was verified by
the acquired resistance
of a large percentage (30 to 50%) of the
coinfected cells to puromycin
(from pBabe-Ras) at P10. In contrast,
both MEF cells (P3) and
MEF cells infected with v-LMP1 alone (P10) were
sensitive to
puromycin.
Interestingly, several cell clones (4 and 19 in two experiments) with
distinct morphology emerged only from cells coinfected
with v-LMP1 and
v-CDK4
R24C, displaying an apparent morphological
transformation at P3 on
cell culture plates, approximately 2 to 3 weeks
after coinfection.
The cells became shorter and much smaller, and they
grew much
faster than all other infected cells. By P5, the entire
population
was largely taken over by these apparently transformed
cells.
At P10, the entire cell population exhibited a complete
morphological
transformation (Fig.
4F) that was not seen for cells
infected
with v-CDK4
R24C (Fig.
4E). Although
v-CDK4
R24C-infected cells exhibited a slightly
extended life span, they
never exhibited this transforming morphology.
In fact, the v-CDK4
R24C-infected cells in two
experiments were passaged once more (P5)
and could not be passaged
further. Thus, LMP1 specifically cooperates
with
CDK4
R24C in inducing cellular morphological
transformation of primary
MEF
cells.
To further examine the transformation properties of cells
coinfected with v-LMP1 and v-CDK4
R24C, a
soft agar assay was performed to demonstrate the anchorage-independent
growth of these cells. About 15% (610 and 650 of 4,000 cells plated
in two separate experiments) of the cells coinfected with v-LMP1
and v-CDK4
R24C at P6 were capable of producing
foci in the soft agar assay (Fig.
6F),
confirming that they were transformed cells. In contrast,
none of the
four individual retroviruses, v-LNSX (P3), v-LMP1
(P6),
v-H-
rasV12 (P3), or
v-CDK4
R24C (P3), resulted in any focus formation
in soft agar, nor did v-LMP1
and v-H-
rasV12
coinfection (P6) (Fig.
6A to E). Cells at a different passage
(P3) were
used in some cases due to the limited passage numbers
of the primary
fibroblasts since none of the infected MEF cells
without v-LMP1 could
be passaged beyond P5. Thus, the results
of the soft agar assay
indicate that LMP1 cooperates with the
CDK4
R24C
gene but not the H-
rasV12 gene in transforming
MEF cells.
View larger version (142K):
[in this window]
[in a new window]
|
FIG. 6.
Cooperative transformation of MEF cells by LMP1 and
CDK4R24C. A soft agar assay was performed with
cells infected with v-LNSX (A), v-LMP1 (B),
v-H-rasV12 (C), v-LMP1 plus
v-H-rasV12 (D),
v-CDK4R24C (E), or v-LMP1 plus
v-CDK4R24C (F). The cells at P6 were used for
cells infected with v-LMP1 (B), v-LMP1 plus
v-H-rasV12 (D), and v-LMP1 plus
v-CDK4R24C (F). Cells at P3 were used for the
other three cultures due to their limited passage numbers (P5 or less).
The foci were counted in two independent experiments (see Results).
|
|
Like that of v-
rasV12, the presence of both
v-LMP1 and v-CDK4
R24C in MEF cells was confirmed
by the acquired resistance of the infected
cells to geneticin and
hygromycin, respectively. It is interesting
that the MEF cells
coinfected with v-LMP1 and v-CDK4
R24C were the
only ones resistant to both geneticin (for v-LMP1) and
hygromycin (for
v-CDK4
R24C [
46]) at P10, and
they were resistant to both drugs despite
the absence of any prior
selection. In addition, Western blot
results with anti-LMP1 antibody
S12 revealed the expression of
LMP1 from cell lysates of all
v-LMP1-infected MEF cultures (Fig.
7A).
Furthermore, an increased level of CDK4 protein could be
detected in
MEF cells infected with v-CDK4
R24C (Fig.
7B).
Thus, the results suggested that cointroduction of
the EBV LMP1 and
cellular CDK4
R24C oncogenes resulted in the
transformation of primary mouse fibroblasts.
View larger version (30K):
[in this window]
[in a new window]
|
FIG. 7.
Detection of LMP1 and CDK4 in infected MEF cells. (A)
Cell lysates were made from MEF cells infected with v-LNSX, v-LMP1,
v-H-rasV12, or v-CDK4R24C
individually or in combinations as indicated and used for Western blot
analysis of LMP1 protein. Controls for LMP1 protein were B95-8
(positive) and MOLT-4 (negative) cells. (B) Cell lysates from MEF cells
infected with v-LNSX, v-LMP1, or v-CDK4R24C
individually or in combination were analyzed for the expression of CDK4
with a CDK4-specific antibody (H-303; Santa Cruz). Although the
endogenous CDK4 is present in the vector-infected cells (MEF-Vector),
an increased level of CDK4 can be observed with
v-CDK4R24C-infected MEF cells. Western blotting
against -actin was used as the loading control.
|
|
MEF cells infected with v-LMP1 were negative for telomerase.
As indicated above, none of the MEF cells infected with v-LNSX,
v-H-rasV12, or v-CDK4R24C
could be passaged beyond P5 in the experiment presented. Because LMP1
is associated with extended passage numbers of MEF cells, we examined
whether the proliferative MEF-LMP1 cells were positive for telomerase.
Cell lysates from parent MEF cells and from MEF infected with v-LMP1 at
P10 were examined for telomerase activity (Fig.
8). HeLa cell lysate was used as a
positive control to indicate the sensitivity of the assay and its
specificity after treatment of the lysate with RNase. The result
indicated that v-LMP1 alone, although it extended the passage number of
MEF cells, was not sufficient to induce telomerase activity. In
contrast, the MEF cells coinfected with v-LMP1 and
v-CDK4R24C were telomerase positive at P10,
consistent with the transformation properties that they acquired. The
v-CDK4R24C-infected MEF cells were not examined
because they had a limited passage history (P5), one passage longer
than that of the v-LNSX cells. The results suggest that although LMP1
efficiently induces the proliferation of MEF cells, additional changes
are likely needed for the MEF-LMP1 cells to become immortal.
View larger version (65K):
[in this window]
[in a new window]
|
FIG. 8.
Detection of telomerase activity in uninfected MEF cells
and in MEF cells infected with v-LMP1 (P10) or v-LMP1 and
v-CDK4R24C (P10). A lysate from HeLa cells was
used as the positive control, and an RNase-treated HeLa cell lysate was
used as the negative control.
|
|
| |
DISCUSSION |
In the work presented here, primary BALB/c MEF cells were used to
study the proliferation and transformation functions of the EBV
transforming gene encoding LMP1. MEF provides a model system free of
any genetic mutation that may complicate the results of the study, and
it is commonly used as a well-defined system to study the effects of
oncogenes in growth stimulation and cell transformation. An
LMP1-expressing retrovirus was used to stably introduce LMP1 into MEF
cells at a high efficiency and allow us to monitor the entire
population of infected MEF cells immediately and continuously
throughout the course of the experiment without any drug selection. As
a result of this new approach, LMP1 was found to have a mitogenic
effect on MEF cells, as indicated by an immediate increase in cell
growth rate. In addition, while MEF cells undergo only a few passages,
the v-LMP1-infected MEF cells can be readily subcultured for up to 30 passages, indicating that LMP1 stimulates the long-term proliferation
of MEF cells. Furthermore, LMP1 cooperates with
CDK4R24C in transforming MEF cells, suggesting
that LMP1 is capable of cooperatively transforming primary rodent
fibroblast cells with a cellular oncogene.
Although LMP1 is essential for EBV-mediated B-cell immortalization,
this is the first demonstration that the LMP1 gene acting alone is
sufficient to induce the proliferation of primary culture cells. The
ability of LMP1 to induce cell proliferation may be important in our
understanding of EBV-associated malignancies. Previous experiments
showed that in addition to a tight association between nasopharyngeal
carcinoma and EBV, most of the cancer cells came from clonal expansions
of single EBV-infected progenitor cells (38), suggesting
that the presence of EBV may provide the initial and fundamental drive
in the process leading to the development of nasopharyngeal carcinoma.
At present, the ability of a single LMP1 gene to induce the
proliferation of primary culture cells is restricted to the model
system of murine fibroblasts. It is obviously of interest to examine
whether this LMP1 retrovirus is sufficient to induce the proliferation
of primary human epithelial cells. It is well known, however, that LMP1
is not sufficient to immortalize primary B cells. Nonetheless, the
system of LMP1-induced MEF proliferation should provide a unique basis
for addressing roles and mechanisms of LMP1 as the sole EBV gene in
cell proliferation and cell cycle regulation.
A variety of different DNA oncogenic viruses, including SV40,
adenovirus, and papillomavirus, are capable of immortalizing primary
rodent fibroblast cells. Two functions are frequently needed for these
viruses to induce the immortalization of primary cells, the
inactivation of Rb, and the suppression of p53 activities through
direct interactions. SV40 large T antigen effectively induces the
immortalization of primary rodent fibroblasts. In addition to its
binding to pRb protein, the interaction between T antigen and tumor
suppressor p53 is also essential for the immortalization (47,
53). In comparison, both adenovirus E1A and HPV E7, although capable of transforming immortalized rodent fibroblast cell lines, do
not effectively immortalize primary cells without the additional partners, adenovirus E1B and HPV E6, respectively (16, 50, 52). The balance between proliferation and abrogation of cell cycle checkpoint is an important feature of these DNA oncogenic viruses. In all of these cases, the viral proteins interfere with the
functions of the p53 tumor suppressor to prevent cell cycle checkpoint
arrest and apoptosis induced by Rb inactivation. Our data here show
that LMP1 is sufficient to effectively induce the proliferation of
primary MEF cells, suggesting that LMP1 could have multiple functions
in growth stimulation and in prevention of cell cycle arrest or
apoptosis induced by abnormal proliferation.
Many studies indicated that the expression of viral or cellular
oncogenes often leads to cell cycle arrest, apoptosis, and cell
senescence that are in part dependent on p53 and its related cell cycle
checkpoints (26, 35). For example, the expression of
adenovirus E1A in primary fibroblast cells results in the stabilization of p53 and the induction of apoptosis (10, 29). Therefore, the ability to neutralize p53 is an essential feature of many DNA
oncogenic viruses. The p53-binding domain of SV40 T antigen is
essential for T antigen to immortalize and transform cells (47,
53). Similarly, both the E1B 55-kilodalton protein of adenovirus
and E6 of HPV can inhibit the activity of p53 through direct
interactions and, in the case of E6, the degradation of p53 protein
(44, 52). Interestingly, the E1B 19-kDa protein is a
homologue of Bcl-2 (4), encoded by a gene that was shown to
be induced by LMP1 (17). Our results raised the possibility that LMP1 can also affect cell cycle checkpoints in the process of
achieving primary cell proliferation. Previous experiments show that
LMP1 is capable of inducing the expression of Bcl-2 (17,
43), activating NF-B activity (19, 32), and
up-regulating the expression of an antiapoptotic gene, A20
(27). All of these activities have been linked to
suppression of cell apoptosis. Indeed, two studies directly demonstrate
the roles of LMP1 in suppressing apoptosis induced by p53 (13,
37). We speculate, based on the ability of LMP1 to induce cell
proliferation without cell apoptosis or growth arrest, that the roles
of LMP1 in suppressing cell death or checkpoint arrest may also be an
important part of LMP1 functions to induce a coordinated cellular
proliferation of primary cells. We are currently investigating the
roles of LMP1 in altering the regulation of genes involved in cell
cycle control and checkpoint regulation.
Although LMP1 induces the proliferation of MEF cells, it is not
sufficient to induce telomerase activity. In fact, no telomerase activity was observed in LMP1-induced proliferative MEF cells at P10.
This result is consistent with a previous finding that in human B cells
transformed with EBV, shortening of telomeres occurred in all
EBV-positive populations until chromosomes had little telomeric DNA
remaining. At this stage, many clones entered into a proliferative
crisis and died, leaving only those with activated telomerase capable
of proliferating indefinitely (9).
The exact mechanisms by which LMP1 induces cellular transformation are
still under investigation. Two recent studies indicate that LMP1 is
involved in induction of JNK (11, 25). The results also
indicate that the LMP1-mediated JNK pathway appears to differ from the
LMP1-induced NF-B pathway. However, it is not clear that either
pathway can explain the roles of LMP1 during its transformation process. Another recent study reveals that LMP1 can activate the Ras
pathway (40). The activated Ras was shown to up-regulate cyclin D1, resulting in the inactivation of Rb through phosphorylation (41). Interestingly, a previous study shows that oncogenic
Ras but not Myc can transform primary mouse fibroblast cells deficient for the p16 gene (45), suggesting such a cooperation may be mediated through the p16/CDK4/D1-to-pRb pathway. Analysis of the cooperation between the LMP1 gene and other oncogenes in inducing the
transformation of primary fibroblast cells may provide a genetic model
system for evaluating the roles of LMP1 and its activated pathways in
the process of LMP1-mediated cellular transformation. Our results
indicate that the LMP1 gene cooperates with
CDK4R24C but not H-rasV12
in transforming MEF cells. The results are consistent with the notion
that LMP1 may exert its transformation function through a Ras-related
pathway. They are also in agreement with previous studies indicating
that Ras readily induces the malignant transformation of MEF cells
established from p16INK4a knockout mouse and
cooperates with a CDK4R24C mutant in
transforming MEF cells (45, 46).
It is worth noting that the cooperative transformation process with
v-LMP1 and v-CDK4R24C may be different from
v-LMP1-induced proliferation. The first sign of morphological
transformation required 2 to 3 weeks with more passages, and it was
found for only a very small percentage of infected cells analyzed for
focus formation on plates (4 and 19 in two experiments). Alternatively,
it is possible, although not very likely based on the viral titers,
that only a small percentage of cells have both viruses and expressed
both proteins. Nonetheless, the transformed cells induced by LMP1 and
CDK4R24C quickly took over the entire
population. The LMP1- and CDK4R24C-transformed
MEF cells present a distinct morphology that is characteristic of the
transformed cells. In addition, they form foci in the soft agar assay,
indicative of anchorage-independent growth. Furthermore, they are
positive for the telomerase activity that is absent in the
proliferative MEF-LMP1 cells. In sum, EBV is a DNA oncogenic virus, and
LMP1 appears to be capable of inducing the proliferation of primary MEF
cells and cooperatively transforming them with another cellular oncogene.
| |
ACKNOWLEDGMENTS |
We are very grateful to F. A. Grasser for the LMP1 plasmid
and D. Thorley-Lawson for antibody S12 against LMP1. We thank J. M. Nicholls for critical reading of the manuscript.
This work was supported by RGC and Croucher grants to L. Cao.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, The University of Hong Kong, Pathology Building, Queen Mary Hospital, Hong Kong, People's Republic of China. Phone:
852-2855-4892. Fax: 852-2855-1241. E-mail:
lcao{at}hkucc.hku.hk.
| |
REFERENCES |
| 1.
|
Ashkenazi, A., and V. M. Dixit.
1998.
Death receptors: signaling and modulation.
Science
281:1305-1308[Abstract/Free Full Text].
|
| 2.
|
Baichwal, V. R., and B. Sugden.
1988.
Transformation of Balb 3T3 cells by the BNLF-1 gene of Epstein-Barr virus.
Oncogene
2:461-467[Medline].
|
| 3.
|
Bartkova, J.,
J. Lukas,
P. Guldberg,
J. Alsner,
A. F. Kirkin,
J. Zeuthen, and J. Bartek.
1996.
The p16-cyclin D/Cdk4-pRb pathway as a functional unit frequently altered in melanoma pathogenesis.
Cancer Res.
56:5475-5483[Abstract/Free Full Text].
|
| 4.
|
Boyd, J. M.,
S. Malstrom,
T. Subramanian,
L. K. Venkatesh,
U. Schaeper,
B. Elangovan,
C. D'Sa-Eipper, and G. Chinnadurai.
1994.
Adenovirus E1B 19 kDa and Bcl-2 proteins interact with a common set of cellular proteins.
Cell
79:341-351[CrossRef][Medline].
|
| 5.
|
Cao, L.,
B. Faha,
M. Dembski,
L. H. Tsai,
E. Harlow, and N. Dyson.
1992.
Independent binding of the retinoblastoma protein and p107 to the transcription factor E2F.
Nature
355:176-179[CrossRef][Medline].
|
| 6.
|
Chen, H. F.,
S. Kevan-Jah,
K. O. Suentzenich,
F. A. Grasser, and N. Mueller-Lantzsch.
1992.
Expression of the Epstein-Barr virus latent membrane protein (LMP) in insect cells and detection of antibodies in human sera against this protein.
Virology
190:106-115[CrossRef][Medline].
|
| 7.
|
Cheng, R. Y.,
P. W. Yuen,
J. M. Nicholls,
Z. Zheng,
W. Wei,
J. S. Sham,
X. H. Yang,
L. Cao,
D. P. Huang, and S. W. Tsao.
1998.
Telomerase activation in nasopharyngeal carcinomas.
Br. J. Cancer
77:456-460[Medline].
|
| 8.
|
Cohen, J. I.,
F. Wang,
J. Mannick, and E. Kieff.
1989.
Epstein-Barr virus nuclear protein 2 is a key determinant of lymphocyte transformation.
Proc. Natl. Acad. Sci. USA
86:9558-9562[Abstract/Free Full Text].
|
| 9.
|
Counter, C. M.,
F. M. Botelho,
P. Wang,
C. B. Harley, and S. Bacchetti.
1994.
Stabilization of short telomeres and telomerase activity accompany immortalization of Epstein-Barr virus-transformed human B lymphocytes.
J. Virol.
68:3410-3414[Abstract/Free Full Text].
|
| 10.
|
Debbas, M., and E. White.
1993.
Wild-type p53 mediates apoptosis by E1A, which is inhibited by E1B.
Genes Dev.
7:546-554[Abstract/Free Full Text].
|
| 11.
|
Eliopoulos, A. G., and L. S. Young.
1998.
Activation of the c-Jun N-terminal kinase (JNK) pathway by the Epstein-Barr virus-encoded latent membrane protein 1 (LMP1).
Oncogene
16:1731-1742[CrossRef][Medline].
|
| 12.
|
Fahraeus, R.,
L. Rymo,
J. S. Rhim, and G. Klein.
1990.
Morphological transformation of human keratinocytes expressing the LMP gene of Epstein-Barr virus.
Nature
345:447-449[CrossRef][Medline].
|
| 13.
|
Fries, K. L.,
W. E. Miller, and N. Raab-Traub.
1996.
Epstein-Barr virus latent membrane protein 1 blocks p53-mediated apoptosis through the induction of the A20 gene.
J. Virol.
70:8653-8659[Abstract].
|
| 14.
|
Gires, O.,
U. Zimber-Strobl,
R. Gonnella,
M. Ueffing,
G. Marschall,
R. Zeidler,
D. Pich, and W. Hammerschmidt.
1997.
Latent membrane protein 1 of Epstein-Barr virus mimics a constitutively active receptor molecule.
EMBO J.
16:6131-6140[CrossRef][Medline].
|
| 15.
|
Hammerschmidt, W., and B. Sugden.
1989.
Genetic analysis of immortalizing functions of Epstein-Barr virus in human B lymphocytes.
Nature
340:393-397[CrossRef][Medline].
|
| 16.
|
Hawley-Nelson, P.,
K. H. Vousden,
N. L. Hubbert,
D. R. Lowy, and J. T. Schiller.
1989.
HPV16 E6 and E7 proteins cooperate to immortalize human foreskin keratinocytes.
EMBO J.
8:3905-3910[Medline].
|
| 17.
|
Henderson, S.,
M. Rowe,
C. Gregory,
D. Croom-Carter,
F. Wang,
R. Longnecker,
E. Kieff, and A. Rickinson.
1991.
Induction of bcl-2 expression by Epstein-Barr virus latent membrane protein 1 protects infected B cells from programmed cell death.
Cell
65:1107-1115[CrossRef][Medline].
|
| 18.
|
Hu, L. F.,
F. Chen,
X. Zheng,
I. Ernberg,
S. L. Cao,
B. Christensson,
G. Klein, and G. Winberg.
1993.
Clonability and tumorigenicity of human epithelial cells expressing the EBV encoded membrane protein LMP1.
Oncogene
8:1575-1583[Medline].
|
| 19.
|
Huen, D. S.,
S. A. Henderson,
D. Croom-Carter, and M. Rowe.
1995.
The Epstein-Barr virus latent membrane protein-1 (LMP1) mediates activation of NF-kappa B and cell surface phenotype via two effector regions in its carboxy-terminal cytoplasmic domain.
Oncogene
10:549-560[Medline].
|
| 20.
|
Izumi, K. M.,
K. M. Kaye, and E. D. Kieff.
1997.
The Epstein-Barr virus LMP1 amino acid sequence that engages tumor necrosis factor receptor associated factors is critical for primary B lymphocyte growth transformation.
Proc. Natl. Acad. Sci. USA
94:1447-1452[Abstract/Free Full Text].
|
| 21.
|
Izumi, K. M., and E. K. Kieff.
1997.
The Epstein-Barr virus oncogene product latent membrane protein 1 engages the tumor necrosis factor receptor-associated death domain protein to mediate B lymphocyte growth transformation and activate NF-kappaB.
Proc. Natl. Acad. Sci. USA
94:12592-12597[Abstract/Free Full Text].
|
| 22.
|
Kaye, K. M.,
K. M. Izumi, and E. Kieff.
1993.
Epstein-Barr virus latent membrane protein 1 is essential for B-lymphocyte growth transformation.
Proc. Natl. Acad. Sci. USA
90:9150-9154[Abstract/Free Full Text].
|
| 23.
|
Kempkes, B.,
D. Spitkovsky,
P. Jansen-Durr,
J. W. Ellwart,
E. Kremmer,
H. J. Delecluse,
C. Rottenberger,
G. W. Bornkamm, and W. Hammerschmidt.
1995.
B-cell proliferation and induction of early G1-regulating proteins by Epstein-Barr virus mutants conditional for EBNA2.
EMBO J.
14:88-96[Medline].
|
| 24.
|
Kieff, E.
1996.
Epstein-Barr virus and its replication, p. 2343-2396.
In
B. N. Fields, D. M. Knipe, P. M. Howley, et al. (ed.), Fields virology, 3rd ed., vol. 2. Lippincott-Raven Publishers, Philadelphia, Pa.
|
| 25.
|
Kieser, A.,
E. Kilger,
O. Gires,
M. Ueffing,
W. Kolch, and W. Hammerschmidt.
1997.
Epstein-Barr virus latent membrane protein-1 triggers AP-1 activity via the c-Jun N-terminal kinase cascade.
EMBO J.
16:6478-6485[CrossRef][Medline].
|
| 26.
|
Ko, L. J., and C. Prives.
1996.
p53: puzzle and paradigm.
Genes Dev.
10:1054-1072[Free Full Text].
|
| 27.
|
Laherty, C. D.,
H. M. Hu,
H. M. Opipari,
F. Wang, and V. M. Dixit.
1992.
The Epstein-Barr virus LMP1 gene product induces A20 zinc finger protein expression by activating nuclear factor kappa B.
J. Biol. Chem.
267:24157-24160[Abstract/Free Full Text].
|
| 28.
|
Lavoie, J. N.,
G. L'Allemain,
A. Brunet,
R. Muller, and J. Pouyssegur.
1996.
Cyclin D1 expression is regulated positively by the p42/p44MAPK and negatively by the p38/HOGMAPK pathway.
J. Biol. Chem.
271:20608-20616[Abstract/Free Full Text].
|
| 29.
|
Lowe, S. W., and H. E. Ruley.
1993.
Stabilization of the p53 tumor suppressor is induced by adenovirus 5 E1A and accompanies apoptosis.
Genes Dev.
7:535-545[Abstract/Free Full Text].
|
| 30.
|
Mann, K. P.,
D. Staunton, and D. A. Thorley-Lawson.
1985.
Epstein-Barr virus-encoded protein found in plasma membranes of transformed cells.
J. Virol.
55:710-720[Abstract/Free Full Text].
|
| 31.
|
Miller, A. D., and G. J. Rosman.
1989.
Improved retroviral vectors for gene transfer and expression.
BioTechniques
7:980-990[Medline].
|
| 32.
|
Mitchell, T., and B. Sugden.
1995.
Stimulation of NF- B-mediated transcription by mutant derivatives of the latent membrane protein of Epstein-Barr virus.
J. Virol.
69:2968-2976[Abstract].
|
| 33.
|
Moorthy, R. K., and D. A. Thorley-Lawson.
1993.
All three domains of the Epstein-Barr virus-encoded latent membrane protein LMP-1 are required for transformation of Rat-1 fibroblasts.
J. Virol.
67:1638-1646[Abstract/Free Full Text].
|
| 34.
|
Mosialos, G.,
M. Birkenbach,
R. Yalamanchili,
T. VanArsdale,
C. Ware, and E. Kieff.
1995.
The Epstein-Barr virus transforming protein LMP1 engages signaling proteins for the tumor necrosis factor receptor family.
Cell
80:389-399[CrossRef][Medline].
|
| 35.
|
Mowat, M. R.
1998.
p53 in tumor progression: life, death, and everything.
Adv. Cancer Res.
74:25-48[Medline].
|
| 36.
|
Nicholson, L. J.,
P. Hopwood,
I. Johannessen,
J. R. Salisbury,
J. Codd,
D. Thorley-Lawson, and D. H. Crawford.
1997.
Epstein-Barr virus latent membrane protein does not inhibit differentiation and induces tumorigenicity of human epithelial cells.
Oncogene
15:275-283[CrossRef][Medline].
|
| 37.
|
Okan, I.,
Y. Wang,
F. Chen,
L. F. Hu,
S. Imreh,
G. Klein, and K. G. Wiman.
1995.
The EBV-encoded LMP1 protein inhibits p53-triggered apoptosis but not growth arrest.
Oncogene
11:1027-1031[Medline].
|
| 38.
|
Raab-Traub, N., and K. Flynn.
1986.
The structure of the termini of the Epstein-Barr virus as a marker of clonal cellular proliferation.
Cell
47:883-889[CrossRef][Medline].
|
| 39.
|
Rickinson, A. B., and E. Kieff.
1996.
Epstein-Barr virus, p. 2397-2446.
In
B. N. Fields, D. M. Knipe, P. M. Howley, et al. (ed.), Fields virology, 3rd ed., vol. 2. Lippincott-Raven Publishers, Philadelphia, Pa.
|
| 40.
|
Roberts, M. L., and N. R. Cooper.
1998.
Activation of a ras-MAPK-dependent pathway by Epstein-Barr virus latent membrane protein 1 is essential for cellular transformation.
Virology
240:93-99[CrossRef][Medline].
|
| 41.
|
Roussel, M. F.
1998.
Key effectors of signal transduction and G1 progression.
Adv. Cancer Res.
74:1-24[Medline].
|
| 42.
|
Rowe, M.,
H. S. Evans,
L. S. Young,
K. Hennessy,
E. Kieff, and A. B. Rickinson.
1987.
Monoclonal antibodies to the latent membrane protein of Epstein-Barr virus reveal heterogeneity of the protein and inducible expression in virus-transformed cells.
J. Gen. Virol.
68:1575-1586[Abstract/Free Full Text].
|
| 43.
|
Rowe, M.,
M. Peng-Pilon,
D. S. Huen,
R. Hardy,
D. Croom-Carter,
E. Lundgren, and A. B. Rickinson.
1994.
Upregulation of bcl-2 by the Epstein-Barr virus latent membrane protein LMP1: a B-cell-specific response that is delayed relative to NF-B activation and to induction of cell surface markers.
J. Virol.
68:5602-5612[Abstract/Free Full Text].
|
| 44.
|
Scheffner, M.,
B. A. Werness,
J. M. Huibregtse,
A. J. Levine, and P. M. Howley.
1990.
The E6 oncoprotein encoded by human papillomavirus types 16 and 18 promotes the degradation of p53.
Cell
63:1129-1136[CrossRef][Medline].
|
| 45.
|
Serrano, M.,
H. Lee,
L. Chin,
C. Cordon-Cardo,
D. Beach, and R. A. DePinho.
1996.
Role of the INK4a locus in tumor suppression and cell mortality.
Cell
85:27-37[CrossRef][Medline].
|
| 46.
|
Serrano, M.,
A. W. Lin,
M. E. McCurrach,
D. Beach, and S. W. Lowe.
1997.
Oncogenic ras provokes premature cell senescence associated with accumulation of p53 and p16INK4a.
Cell
88:593-602[CrossRef][Medline].
|
| 47.
|
Srinivasan, A.,
K. W. Peden, and J. M. Pipas.
1989.
The large tumor antigen of simian virus 40 encodes at least two distinct transforming functions.
J. Virol.
63:5459-5463[Abstract/Free Full Text].
|
| 48.
|
Tomkinson, B.,
E. Robertson, and E. Kieff.
1993.
Epstein-Barr virus nuclear proteins EBNA-3A and EBNA-3C are essential for B-lymphocyte growth transformation.
J. Virol.
67:2014-2025[Abstract/Free Full Text].
|
| 49.
|
Wang, D.,
D. Liebowitz, and E. Kieff.
1985.
An EBV membrane protein expressed in immortalized lymphocytes transforms established rodent cells.
Cell
43:831-840[CrossRef][Medline].
|
| 50.
|
Watanabe, S.,
T. Kanda, and K. Yoshiike.
1989.
Human papillomavirus type 16 transformation of primary human embryonic fibroblasts requires expression of open reading frames E6 and E7.
J. Virol.
63:965-969[Abstract/Free Full Text].
|
| 51.
|
Wolfel, T.,
M. Hauer,
J. Schneider,
M. Serrano,
C. Wolfel,
E. Klehmann-Hieb,
E. De Plaen,
T. Hankeln,
K. H. Meyer zum Buschenfelde, and D. Beach.
1995.
A p16INK4a-insensitive CDK4 mutant targeted by cytolytic T lymphocytes in a human melanoma.
Science
269:1281-1284[Abstract/Free Full Text].
|
| 52.
|
Yew, P. R., and A. J. Berk.
1992.
Inhibition of p53 transactivation required for transformation by adenovirus early 1B protein.
Nature
357:82-85[CrossRef][Medline].
|
| 53.
|
Zhu, J.,
P. W. Rice,
L. Gorsch,
M. Abate, and C. N. Cole.
1992.
Transformation of a continuous rat embryo fibroblast cell line requires three separate domains of simian virus 40 large T antigen.
J. Virol.
66:2780-2791[Abstract/Free Full Text].
|
Journal of Virology, January 2000, p. 883-891, Vol. 74, No. 2
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Ohtani, N., Brennan, P., Gaubatz, S., Sanij, E., Hertzog, P., Wolvetang, E., Ghysdael, J., Rowe, M., Hara, E.
(2003). Epstein-Barr virus LMP1 blocks p16INK4a-RB pathway by promoting nuclear export of E2F4/5. JCB
162: 173-183
[Abstract]
[Full Text]
-
Xin, B., He, Z., Yang, X., Chan, C.-P., Ng, M.-H., Cao, L.
(2001). TRADD Domain of Epstein-Barr Virus Transforming Protein LMP1 Is Essential for Inducing Immortalization and Suppressing Senescence of Primary Rodent Fibroblasts. J. Virol.
75: 3010-3015
[Abstract]
[Full Text]
-
He, Z., Xin, B., Yang, X., Chan, C.-p., Cao, L.
(2000). Nuclear Factor-{{kappa}}B Activation Is Involved in LMP1-mediated Transformation and Tumorigenesis of Rat-1 Fibroblasts. Cancer Res.
60: 1845-1848
[Abstract]
[Full Text]
Top
Abstract
Introduction
