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Molecular and Cellular Biology, February 2000, p. 1344-1360, Vol. 20, No. 4
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Epstein-Barr Virus Suppresses a G2/M
Checkpoint Activated by Genotoxins
Mark
Wade and
Martin J.
Allday*
Section of Virology and Cell Biology and
Ludwig Institute for Cancer Research, Imperial College of Science
Technology and Medicine, London W2 1PG, United Kingdom
Received 19 July 1999/Returned for modification 9 September
1999/Accepted 9 November 1999
 |
ABSTRACT |
Several Epstein-Barr virus (EBV)-negative Burkitt lymphoma-derived
cell lines (for example, BL41 and Ramos) are extremely sensitive to
genotoxic drugs despite being functionally null for the tumor
suppressor p53. They rapidly undergo apoptosis, largely from
G2/M of the cell cycle. 5-Bromo-2'-deoxyuridine labeling experiments showed that although the treated cells can pass through S
phase, they are unable to complete cell division, suggesting that a
G2/M checkpoint is activated. Surprisingly, latent
infection of these genotoxin-sensitive cells with EBV protects them
from both apoptosis and cell cycle arrest, allowing them to complete the division cycle. However, a comparison with EBV-immortalized B-lymphoblastoid cell lines (which have functional p53) showed that EBV
does not block apoptosis per se but rather abrogates the activation of,
or signalling from, the checkpoint in G2/M. Furthermore,
analyses of BL41 and Ramos cells latently infected with P3HR1 mutant
virus, which expresses only a subset of the latent viral genes, showed
that LMP-1, the main antiapoptotic latent protein encoded by EBV, is
not involved in the protection afforded here by viral infection. This
conclusion was confirmed by analysis of clones of BL41 stably
expressing LMP-1 from a transfected plasmid, which respond like the
parental cell line. Although steady-state levels of Bcl-2 and related
proteins varied between BL41 lines and clones, they did not change
significantly during apoptosis, nor was the level of any of these anti-
or proapoptotic proteins predictive of the outcome of treatment. We
have demonstrated that a subset of EBV latent gene products can
inactivate a cell cycle checkpoint for monitoring the fidelity and
timing of cell division and therefore genomic integrity. This is likely
to be important in EBV-associated growth transformation of B cells and
perhaps tumorigenesis. Furthermore, this study suggests that EBV will be a unique tool for investigating the intimate relationship between cell cycle regulation and apoptosis.
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INTRODUCTION |
The majority of effective anticancer
chemotherapeutic agents are genotoxins which work by causing DNA
damage, either by directly modifying DNA or inhibiting DNA metabolic
enzymes (18, 55). Such agents can activate several different
biochemical pathways, including those featuring c-Abl tyrosine kinase,
c-Jun amino-terminal kinases, and the tumor suppressor p53. However,
because it appears to be activated in response to all genotoxic agents,
p53 is widely considered to be the major sensor of genotoxic stress
(8, 20, 37). Damage to DNA, the depletion of
ribonucleotide pools, and hypoxia all lead to the accumulation and
activation of nuclear p53. This increase in the stability of p53
appears to be the critical link between DNA damage, cell cycle
checkpoints, and programmed cell death (apoptosis). Cells with
wild-type p53 typically respond to genotoxic stress by arresting in
G1 and sometimes G2/M of the cell cycle or
undergoing apoptosis. Although the biochemical details of the
G1 checkpoint are reasonably well understood, the precise roles of p53 in G2/M arrest and in the activation of
apoptosis are far less clearly defined (6, 31, 35).
Mutation of p53 occurs in over half of human tumors (27),
and such mutants are generally defective in the ability to induce growth arrest and apoptosis (31, 35). Moreover, since
p53-deficient rodent cells are resistant to a diverse group of
anticancer drugs and radiation, this led to the view that loss of the
p53 apoptosis function is responsible for cross-resistance to
anticancer agents (17, 38-40, 57).
Although the hypothesis that cells die from cancer treatment due to
apoptosis largely controlled by wild-type p53 is very attractive,
several reports suggest that the status of p53 does not always affect
sensitivity to DNA-damaging drugs (5). Also, there have been
a number of reports of tumor-derived cells which are null for p53
function but are readily induced to undergo apoptosis by genotoxic
drugs and/or ionizing radiation. It is perhaps no coincidence that the
cells studied were all of hematological origin: T-lymphoma cells from
p53
/ mice (49), human promyelocytic leukemia
HL60 cells (23), human Burkitt B-lymphoma cells
(2), and human T-cell acute lymphoblastic leukemia cells
(51) are all induced to undergo p53-independent apoptosis;
in each case, it was concluded that this might be activated from a
checkpoint in G2/M of the cell cycle.
Although the DNA damage response mechanisms in G2/M are
well defined for yeast, relatively little is known about the molecular events in mammalian cells (24, 46, 55). It is assumed that G2/M cell cycle targets are largely conserved between yeast
and mammals. The best example of this is in the control of
G2-to-M progression. Recent studies have shown that
tyrosine phosphorylation of the human Cdc2 prevents entry into mitosis
in the presence of damaged or unreplicated DNA (4, 28).
Furthermore, the human homologue of Chk1 is phosphorylated in response
to DNA damage and binds to and phosphorylates human Cdc25C phosphatase.
This allows binding of a 14-3-3 protein to Cdc25C which inactivates the
latter and is thought to lead to a G2 arrest by preventing the dephosphorylation of Cdc2. However, DNA damage responses in mammalian cells are complex: other levels of G2 control
(including p53 [6]) are thought to operate; in
addition, mitotic checkpoints may be involved (46). The
relationship between the induction of apoptosis and G2/M
checkpoints is not well understood; nevertheless, survivin, an
inhibitor of apoptosis protein, has recently been shown to counteract a
default induction of apoptosis in the G2/M phase of the
cell cycle (36). Although this finding suggests that the
control of apoptosis and progression of the cell cycle are intimately
linked throughout the cycle, little is known about the molecular
mechanisms which connect the two.
In vitro, Epstein-Barr virus (EBV) can induce the continuous
proliferation of a subset of resting human B cells. The resulting immortalized lymphoblastoid cell lines (LCLs) are similar in phenotype to physiologically activated B lymphoblasts and express nine latent viral proteins: nuclear antigens EBNA1, -2, -3A, -3B, and -3C and
EBNA-LP and the latent membrane proteins LMP-1, LMP-2A, and LMP-2B
(29). In addition to inducing continuous cell division, it
has been suggested that these latent proteins may also facilitate cell
survival by suppressing the apoptotic program.
The first indication that EBV latent gene expression might enhance
B-cell survival by antagonizing cell death, rather than inducing
proliferation, came when it was realized that the sensitivity of type 1 Burkitt lymphoma (BL) cell lines (which express only EBNA1) and many
EBV-negative BL cell lines when grown in vitro resulted from their
tendency to suddenly undergo apoptosis if culture conditions were
suboptimal. On the other hand, BL cells which had drifted in culture to
a type 3 latency (expressing all of the known viral latency-associated
proteins) were, like LCLs, relatively resistant to a variety of
triggers of apoptosis, including serum deprivation and Ca2+
ionophores. Cultured EBV-negative BL cells converted to the latency type 3 state by infection with the B95-8 strain of EBV also became more
resistant; however, those converted with the mutant P3HR1 virus (which
fail to express EBNA2, EBNA-LP, and the latent membrane proteins) were
not protected (22). Generally, BL type 1 cells express
relatively little of the antiapoptotic protein Bcl-2, and transfection
of Bcl-2 could enhance the survival of these cells. The EBV gene
capable of mimicking transfected Bcl-2 was the LMP-1 gene, and it
appeared to do so by inducing endogenous Bcl-2 expression
(26). Subsequently it was shown that LMP-1 may contribute to
the survival of B cells latently infected with EBV by at least two
other mechanisms. There are numerous reports that LMP-1 can activate
the transcription factor NF-
B (15, 29), and one
consequence of this is induction of the A20 zinc finger protein. A20
has been shown to provide protection from apoptosis induced by tumor
necrosis factor alpha (TNF-
), and it has been suggested that in
epithelial cells it might suppress p53-mediated death (19, 32,
43). Also, there has been a report that LMP-1 can induce the
expression of the inhibitor of apoptosis, Mcl-1 (56). A
further link between LMP-1 and the death/survival apparatus was
revealed when its association with TNF receptor (TNFR)-associated
factors and its similarities to CD40 were elucidated (7, 11, 13,
30). LMP-1 may constitutively activate growth/survival signals
via TNFR-associated factor molecules independently of TNFR or CD40
ligation and thus contribute to the suppression of apoptosis via
pathways which involve neither Bcl-2, Mcl-1, nor A20.
DNA tumor viruses such as simian virus 40, adenovirus, and human
papillomavirus encode oncoproteins which interact with the tumor
suppressor p53. The function of p53 is suppressed by all three viral
oncoproteins: p53 is inactivated by the simian virus 40 T antigen and
by the adenovirus E1B 55K protein and is degraded in response to human
papillomavirus type 16 E6 (53). In contrast, although EBV
can very efficiently immortalize resting B cells to produce LCLs, there
is no evidence to suggest that EBV gene expression interferes with the
function of p53 in these continuously proliferating cells (2, 3,
10, 33, 45). During infection of normal human resting primary B
cells, EBV gene expression activates transcription of the p53 gene to a
level similar to that in mitogen-treated cells; this produces a normal,
physiologically tolerable, low level of p53 which is compatible
with proliferation. This process also primes the cells for
activation of p53-mediated apoptosis if the proliferating B cells are
subsequently treated with DNA-damaging drugs such as cisplatin (2,
3). It seems, therefore, that LMP-1 has antiapoptotic activity in
certain situations but does not inhibit the p53-mediated DNA damage
response in LCLs. Consistent with this failure of LMP-1 to universally
suppress apoptosis, its expression in LCLs does not block Fas-mediated
death (14).
Although EBV latent gene expression actually sensitizes LCLs to
p53-mediated apoptosis initiated from G1/S, here we show
that in converted BL cells
which are functionally null for p53EBV can inhibit the activation of the apoptosis program from a
G2/M checkpoint normally activated by genotoxic drugs. A
function(s) of latent EBV either specifically protects against a
p53-independent form of apoptosis or, more likely, abrogates the
activation of or signalling from a G2/M cell cycle
checkpoint. This activity neither involves nor requires LMP-1.
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MATERIALS AND METHODS |
Cell culture and genotoxin treatments.
Ramos BL cell line
and the EBV P3HR1-converted lines AW-Ramos and EHRB-Ramos were cultured
in RPMI 1640 medium supplemented with penicillin, streptomycin,
glutamine, and 10% fetal calf serum (Gibco BRL) and maintained at
37°C in a 10% CO2 incubator. All other cell lines were
cultured in RPMI 1640 supplemented with penicillin, streptomycin,
glutamine, and 10% Serum Supreme (BioWhittaker, Wokingham, United
Kingdom) and maintained at 37°C in a 10% CO2 incubator.
Cell lines were routinely fed at a dilution of 1:4; for experimental
analysis, cells were diluted to a concentration of 3 × 105/ml 24 h prior to manipulation. Cisplatin (David
Bull Laboratories, Mulgrave, Australia), doxorubicin (Pharmacia,
Amersham, United Kingdom), etoposide (Bristol-Myers, Hounslow, United
Kingdom), and camptothecin (Sigma, United Kingdom) were each titrated
for ability to induce apoptosis by dose-response experiments in the BL41 cell line.
Viral infection of Ramos cells.
Cells (107) were
incubated in 1 ml of EBV (purified by ultrafiltration from the marmoset
B95.8 cell line) for 2 h at 37°C in a 10% CO2
incubator. Mock-infected cells were incubated in supplemented RPMI 1640 medium. All cells were then diluted to 106/ml overnight,
and the total volume was diluted 1:3 in medium. After 3 days, cells
were diluted to 3 × 105/ml before experimental manipulation.
Western blot analysis.
Cells were washed twice in
phosphate-buffered saline (PBS) and lysed in radioimmunoprecipitation
assay lysis buffer (50 mM Tris [pH 8.0], 150 mM NaCl, 1% NP-40,
0.5% deoxycholate, 0.1% sodium dodecyl sulfate [SDS], 1 mM
phenylmethylsulfonyl fluoride, Complete protease inhibitor) for 10 min
on ice. After centrifugation at 4°C for 10 min, the supernatant was
removed and protein concentration was estimated colorimetrically using
the Bio-Rad detergent-compatible assay. Then 50 µg of protein
was added to an equal volume of 2× SDS protein sample buffer (60 mM
Tris [pH 6.8], 2% [wt/vol], SDS, 20% [vol/vol] glycerol, 2%
[vol/vol] 
-mercaptoethanol, 2% bromophenol blue) and loaded onto
SDS-polyacrylamide gels [7.5% gels for poly(ADP-ribose) polymerase
(PARP) and p53; 12.5% for the Bcl-2 family of proteins; 10% for EBV
antigens]. Gels were transferred for 4 h at 4°C onto a Protran
nitrocellulose membrane. Nonspecific antibody binding was
prevented by blocking in PBS-0.05% Tween 20-5% Marvel (PBS-M) for 1 h. After incubation with rabbit primary polyclonal
antibody (PAb) overnight at 4°C, membranes were washed in changes of
PBS-0.05% Tween 20 for a total of 1 h, incubated with goat
anti-rabbit secondary antibody (1:2,000 in PBS-M) conjugated to
horseradish peroxidase for 1 h, then washed as previously, and
visualized by enhanced chemiluminescence (Amersham, Little Chalfont,
United Kingdom) as recommended by the supplier.
For primary monoclonal antibodies (MAbs), an intermediate incubation
with rabbit anti-mouse PAb (1:1,000) was performed before washing and
addition of horseradish peroxidase-conjugated antibody (1:10,000) for
25 min before visualization.
Antibodies.
Rabbit PAb to PARP was from Boehringer Mannheim,
Lewes, United Kingdom. Mouse MAb to Bcl-2 was from DAKO, High Wycombe,
United Kingdom. MAb DO-1 to p53 was a gift from Xin Lu, Ludwig
Institute for Cancer Research, London, United Kingdom.
PAbs to Bax (N-20) and Mcl-1 (S-19) were from Santa Cruz Biotechnology
Inc., San Diego, Calif. Anti Bcl-X PAb (AF800) was
from R&D,
Minneapolis, Minn. The MAb to EBNA2 (PE-2) was from
DAKO. Human serum
to the type II strain of EBV was a gift from
Paul Farrell, Ludwig
Institute for Cancer Research. MAb S12 was
used to detect LMP-1
(
41), and MAb JF186 was used to detect
EBNA-LP
(
16).
FACS analysis.
For estimation of population cell cycle
distribution by fluorescence-activated cell sorting (FACS), cells were
washed twice in PBS, spun at 2,000 rpm for 3 min, resuspended in 500 ml
of ice-cold 70% ethanol, and resuspended in 500 ml of propidium iodide (PI) solution (18 µg of PI and 8 µg of RNase A per ml; stock
reagents from Sigma) or stored at 
20°C until analysis.
BrdU labeling.
Cells were incubated with
5-bromo-2'-deoxyuridine (Sigma) at a concentration of 10 µM for
1 h, after which the pulse was washed out with prewarmed sterile
PBS and cells were resuspended in fresh medium containing no label.
Cisplatin was immediately added to the flasks, and 2 × 106 cells were harvested at each time point, centrifuged at
1,300 rpm for 5 min, washed twice in 2 ml of 1% bovine serum albumin (BSA) in PBS, and resuspended in 500 µl of ice-cold 70% ethanol on
ice for 30 min before storage at 20°C or direct analysis. Cells
were washed in PBS before thorough resuspension in 750 µl of 2 N HCl
containing 0.5% (vol/vol) Triton X-100 for 30 min at room temperature
(RT) to denature the labeled, double-stranded DNA. Acid was neutralized
by resuspending cells in 750 µl of 0.1 M sodium tetraborate (pH 8.5)
and incubation at RT for 5 min. Cells were centrifuged and resuspended
in 20 µl of fluorescein isothiocyanate (FITC)-conjugated anti-BrdU
antibody (Becton Dickinson, Oxford, United Kingdom), which was then
further diluted with 380 µl of 1% BSA-0.5% Tween 20-PBS. After
incubation in the dark at RT for 30 min, cells were washed twice in
0.5% Tween 20-PBS and resuspended in 500 µl of PI solution.
Acridine orange staining.
A total of 8 × 104 cells were harvested, washed in PBS twice, and
resuspended in acridine orange (1 µg/ml in PBS; Sigma) before mounting on slides (Shandon, Pittsburgh, Pa.) and visualization on a
Zeiss Axiophot fluorescence microscope (Carl Zeiss, Jena, Germany) at
488 nm.
TUNEL.
For terminal deoxynucleotidyltransferase-mediated
dUTP-biotin nick end labeling (TUNEL) analysis, cells were analyzed
using an FITC in situ cell death detection kit (Boehringer Manheim). Briefly, 2 × 106 cells were harvested at each time
point and resuspended in 200 µl of PBS. An equal volume of freshly
made 2% formaldehyde-PBS solution was added, and cells were fixed for
30 min at RT with agitation. Cells were washed twice in PBS and stored
in 500 µl of 80% ethanol until analysis. After washing in PBS, cells
were permeabilized with 100 µl of 0.1% (vol/vol) Triton X-100 in
0.1% sodium citrate for 5 min on ice. Cells were then incubated at 37°C for 90 min in a ratio of enzyme to FITC label solution as instructed by the manufacturer before a final wash in PBS and resuspension in PI solution. All analyses were performed on a FACSort
flow cytometer using CellQuest software (Becton-Dickinson).
EBNA-LP-TUNEL double staining.
One million cells were
harvested from Ramos or Ramos cells newly infected with EBV prior to
and 16 h after addition of cisplatin. Cells were washed in PBS,
and cytospins of 8 × 104 cells were made. After air
drying, cells were fixed in methanol-acetone (1:1) for 20 min at
20°C. After rehydration in PBS for 10 min, cells were permeabilized
and analyzed by TUNEL as described above. Following two washes in PBS,
cytospins were incubated with anti-EBNA-LP antibody JF186 (1:10) for
1 h, washed in PBS, and then incubated with tetramethyl rhodamine
isothiocyanate-labeled goat anti-mouse antibody (1:50) for 1 h.
All antibody incubations were at RT in a humid chamber. After a final
wash, slides were mounted in Citifluor (Citifluor, London, United
Kingdom) and visualized for TUNEL and EBNA-LP positivity on a Zeiss
Axiovert 100M confocal imaging microscope using excitation wavelengths
of 488 and 543 nm, respectively. Images were processed using Zeiss
LSM510 software.
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RESULTS |
Three BL-derived cell lines, BL41, Ramos, and Louckes, were
previously identified as being very sensitive to cisplatin-induced apoptosis despite being functionally null for p53 (2). Due to mutation and loss of heterozygosity, the cells of all three lines
express only a single p53 allele encoding a protein which is
transcriptionally defective and, in the case of BL41 (p53, Arg248Gln)
and Ramos (p53, Ile254Asp) has been shown to be defective for the
induction of apoptosis when expressed ectopically (2). After
16 h of treatment with cisplatin, these BL-derived cells did not
appear to arrest in G1 after treatment with cisplatin, nor
was a significant sub-G1 populationnormally
characteristic of apoptosisrevealed by flow cytometry (2).
The data were consistent with earlier reports that cisplatin could
sometimes induce apoptosis from G2 in some murine tumor
cells (48). In the present study, initially BL41 and then
Ramos cells were used to investigate further the nature of this
p53-independent apoptosis which is induced by cisplatin and apparently
activated in G2 or M of the cell cycle.
Various genotoxic drugs induce PARP cleavage but not a significant
sub-G1 population in BL41 cells.
Various recent
reports have shown that activation of CPP32 (Yama or caspase 3) is
increased in many cells undergoing apoptosis, and the proteolytic
cleavage of one of its substrates, PARP, is now widely accepted as a
hallmark of apoptosis (9, 25, 52). To determine whether the
apoptosis which is apparently associated with G2/M in BL41
cells was characterized by cleavage of PARP and also generally
associated with DNA damage in these cells, we performed experiments
with cisplatin and three other genotoxic drugs and analyzed the results
by Western blotting. Doxorubicin (adriamycin; which cross-links DNA),
etoposide (a DNA topoisomerase II inhibitor), and camptothecin (a DNA
topoisomerase I inhibitor) were all tested for their effect on BL41
cells. All four drugs induced nearly complete or complete proteolytic
cleavage of PARP from 110 to 89 kDa within 12 h or less (Fig.
1A). Samples of the cells from the time
point first showing 100% cleavage of PARP were collected, stained with
PI, and analyzed by flow cytometry (Fig. 1B). It should be noted that
by this time the majority of cells in each drug-treated culture also
appeared apoptotic by morphological criteria (data not shown and Fig.
6B, center panel).
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FIG. 1.
Various genotoxic drugs induce PARP cleavage but not
necessarily a sub-G1 population in FACS analysis. BL41
cells were treated for 16 h with genotoxins (cisplatin, 10 µg/ml; doxorubicin, 5 µg/ml; etoposide, 10 µg/ml; camptothecin, 3 µg/ml). (A) Cells were harvested at 4-h intervals and assessed for
PARP cleavage by Western blotting: (0 h [tracks 1, 6, 11, and 16],
4 h [tracks 2, 7, 12, and 17], 8 h [tracks 3, 8, 13, and
18], 12 h [tracks 4, 9, 14, and 19], and 16 h [tracks 5, 10, 15, and 20]). (B) Samples were also subjected to FACS analysis for
cell cycle distribution. Cell cycle profiles corresponding to time
points at which PARP cleavage was judged to be 100% are shown.
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As with cisplatin treatment, these apoptotic cells produced cell cycle
profiles which were very similar to those of the proliferating,
untreated BL41 cells (Fig.
1B, top panel). The exception in this
particular experiment were the cells treated with etoposide, which
showed a minor increase in the sub-G
1 population
(<10%)
but by
the criterion of PARP cleavage, 100% of these cells
were already
apoptotic. All of these data are consistent with
cisplatin, doxorubicin,
etoposide, and camptothecin activating
p53-independent apoptosis
late in the cell cycle, in G
2 or
mitosis, when the cells have
duplicated their DNA and have a 4N
content. Activation of this
checkpoint is not restricted to cisplatin
but appears to be generally
associated with chemical agents which
induce DNA strand
breaks.
BL41 cells treated with cisplatin after BrdU incorporation pass
through S phase but do not reenter G1.
To investigate
further the nature of these cell cycle phenomena, a multiparameter flow
cytometric assay was devised to establish more precisely the fate of
BL41 cells after treatment with cisplatin. Cells were incubated for
1 h in growth medium containing BrdU; after the excess BrdU was
washed out, the cells were placed back in normal medium. After further
incubation with or without cisplatin, cells were stained with an
FITC-conjugated anti-BrdU antibody to identify cells undergoing DNA
synthesis during the pulse period and PI to stain the total DNA and
show their cell cycle distribution. An example of such an experiment is
shown in Fig. 2. The proliferating, untreated BL41 cells shown in Fig. 2A, panel 1 (0h), were replaced in
normal growth medium after a 1-h BrdU pulse. The cells which were
synthesizing DNA during this labeling period can be seen as the
FITC-positive S-phase population. These cells are shown schematically
as ii and iii in Fig. 2C. During the following 12 h, this labeled
population of cells passes through G2/M; the cells undergo
cytokinesis, complete cell division, and reappear as a BrdU-labeled
G1 (2N) population. Some of this population then enters a
second S phase (since BrdU-labeling) between 12 and 16 h (Fig. 2A,
panels 5 and 6).
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FIG. 2.
After treatment with cisplatin (10 µg/ml), BL41 cells
pass through S phase but do not divide and reenter G1. BL41
cells were pulsed with BrdU and harvested at time intervals shown in
the top right of each plot prior to staining with FITC-labeled
anti-BrdU antibody (y axis) and PI (x axis). (A)
Untreated cells. An asterisk indicates cells which have traversed S and
completed mitosis since the start of the experiment. (B) Cells
incubated in the presence of cisplatin. Note the absence of cells which
have completed mitosis. (C) Schematic diagram of asynchronously growing
cells labeled with BrdU. (i) G0/G1 cells which
did not incorporate BrdU during the labeling period; (ii) labeled cells
in early- and mid-S phase; (iii) cells in late S phase and
G2/M; (iv) unlabeled cells in G2/M. The area
above the dotted line was electronically gated to examine progression
of S-phase cells through the cell cycle during the course of the
subsequent experiments.
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Figure
2B shows the cells which were treated with cisplatin after the
BrdU pulse. At 4 h, there is little difference between
this
population and the untreated population (compare Fig.
2A,
panel 3, with
Fig.
2B, panel 3). In contrast, by 8 h it is apparent
that
cisplatin treatment prevents the cells from completing cell
division; a
BrdU-labeled G
1 does not emerge. This is even more
pronounced by 12 h (compare Fig.
2B, panel 5, with Fig.
2A, panel
5).
After 16 h, the untreated cells can be seen as two discrete
populations, labeled and unlabeled, each distributed in all phases
of
the cell cycle. However, the cells treated with cisplatin appear
to be
accumulating in S phase, and the unlabeled G
1 population
is
apparently increasing. At this stage, by the criteria of PARP
cleavage
and morphology (see Fig.
6B, center panel), most of these
cells have
undergone apoptosis. We conclude that this distribution
of cells must
have derived from 4N cells in which chromatin condensation
has occurred
and nuclease has been activated, and as a consequence
the DNA has a
reduced affinity for both PI and anti-BrdU antibody.
The apparently
expanded G
1 population in fact consists largely
of 4N cells
with an apoptotic
morphology.
When the cells which stained positive for BrdU were electronically
gated (as shown schematically in Fig.
2C) and plotted as
a cell cycle
histogram (cell number versus PI staining), the emergence
of a labeled
G
1 is very obvious in the untreated cells. The increase
in
an apoptotic population derived from 4N (G
2/M) cells, which
becomes superimposed on S phase (indicated with an arrow in Fig.
3B, panel 6) and to a lesser degree
the G
1 phase, becomes very
obvious in the
cisplatin-treated cells (compare panels 6 in Fig.
3A and B and
also Fig.
2A and B).
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FIG. 3.
BL41 cells treated with cisplatin fail to complete
mitosis and instead undergo apoptosis. Cells were electronically gated
as described for Fig. 2C. A significant proportion of untreated
BrdU-labeled BL41 cells (A) have returned to G1 phase by
12 h, while BL41 cells treated with cisplatin (B) are unable to
complete mitosis (compare graphs 5 in panels A and B). The apparent
increase in cells in S phase (indicated with an arrow) in graph 6 is
derived from cells which have undergone apoptosis from
G2/M.
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BL cells latently infected with B95.8 EBV are protected from
apoptosis induced by genotoxins.
Latent infection with EBV has
been shown to protect some EBV-negative BL cells from apoptosis induced
by either reduced serum or the action of Ca2+ ionophores.
The EBV protein largely thought to be responsible for this
antiapoptotic activity is LMP-1 (see the introduction). However, we
previously showed that expression of the same complement of latent EBV
genes (see the introduction and below) does not protect
EBV-immortalized B-LCLs, which are wild type for p53, from apoptosis
induced by a range of genotoxins (2, 3). To investigate the
effect of EBV on the p53-independent apoptosis seen in BL41, we treated
cells stably infected with the B95.8 strain of EBV with cisplatin and
compared their response with that of the parental line. As expected,
Western blot analysis of BL41 showed considerable proteolytic cleavage
of PARP by 8 h after addition of cisplatin. However, even after
16 h of exposure to cisplatin, Western blots of the converted
BL41/B95.8 cells showed no trace of PARP cleavage (Fig.
4). Consistent with these cells failing
to undergo apoptosis, very few, if any, cells with the distinctive
morphology of apoptotic lymphocytes were detected by microscopic
examination of the cultures up to 20 h after addition of cisplatin
(Fig. 6B, right panel). By these criteria, EBV latent gene expression
had prevented apoptosis induced by this genotoxin. Similar experiments
performed with doxorubicin, etoposide, and camptothecin produced
similar results: protection from genotoxin-induced apoptosis by EBV
(data not shown). However, it should be noted that these EBV-carrying
cells are capable of undergoing apoptosis in response to other stimuli
such as ceramide and H2O2 (our unpublished observations).
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FIG. 4.
EBV protects against cisplatin-induced apoptosis. BL41
and BL41/B95.8 cells were incubated with cisplatin (10 µg/ml),
harvested at 4-h intervals, and assessed for PARP cleavage by Western
blotting. Note the complete absence of PARP cleavage even at 16 h
in the EBV-positive cells. The BL41/B95.8 cells used were judged to be
100% EBV positive by immunofluorescence staining with an anti-EBNA-LP
MAb (not shown).
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EBV latent gene expression suppresses the G2/M
checkpoint.
To determine the effect of EBV latent gene expression
on the cell cycle responses to genotoxic damage, we performed further experiments in which the behavior of the BrdU-labeled cells was monitored in the presence and absence of cisplatin. BL41/B95.8 cells
were pulse-labeled as described above, and then cisplatin was added to
half of the sample. The outcome of treatment can be compared with
similar treatment of BL41 cells and with untreated BL41 cells in Fig.
5 and 6A.
Sixteen hours after the addition of cisplatin, the labeled,
EBV-infected BL41/B95.8 cells have reemerged from G2/M to
produce a BrdU-positive G1 population similar to that seen
in the untreated BL41 cells. Expression of EBV latency genes in these
BL-derived cell lines produces cells in which the G2/M
checkpoint is apparently suppressed. The cells behave almost as if
cisplatin had not been added to the medium since a significant proportion of the population complete the cell division cycle (see also
Fig. 9A, bottom left-hand panel). It should be noted that anti-EBNA-LP
immunofluorescence staining showed that 100% of the BL41/B95.8 cells
were latently infected with EBV (data not shown). Figure 6B shows that
16 h posttreatment, BL41 cells are almost exclusively apoptotic
and therefore cannot be cycling (Fig. 6B, compare left and middle
panels), while BL41/B95.8 cells appear morphologically normal at the
same time point (Fig. 6B, right panel).
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FIG. 5.
BL41/B95.8 cells complete cell division after treatment
with cisplatin (10 µg/ml). While by 12 h a significant
proportion of untreated BL41 cells have completed mitosis (asterisk,
12 h), cisplatin-treated cells are unable to do so and instead
undergo apoptosis (middle column). However, latent infection with EBV
allows BL41 cells to complete mitosis in the presence of cisplatin
(right column).
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FIG. 6.
(A) Electronically gated BrdU-labeled
BL41/B95.8 cells. The data presented in Fig. 5 were electronically
gated as described for Fig. 2. Note the reemergence of a BrdU-labeled
G1 population of cisplatin-treated BL41/B95.8 cells (right
column, 12h and 16h) which is absent in treated parental BL41 cells
(middle column). (B) Morphology as shown by acridine orange staining.
BL41 cells treated with cisplatin for 16 h (center) all have a
characteristic apoptotic morphology. Untreated BL41 and
cisplatin-treated BL41/B95.8 cells show the regular nuclear morphology
of healthy proliferating B cells.
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|
De novo infection of Ramos cells with EBV confers resistance to
cisplatin-induced apoptosis.
To eliminate the possibility that
protection in the established cell lines was due to an unknown
selection process occurring after infection, we infected both BL41 and
another cisplatin-sensitive BL cell line, Ramos, with the B95.8 strain
of EBV and evaluated their response to cisplatin 72 h after
infection. There was no significant increase in cell death in the
infected cell cultures compared to mock-infected cells, and infection
of Ramos cells consistently yielded a higher percentage of
EBV-positive cells than infection of BL41 cells (data not shown);
therefore, B95.8-infected Ramos cells were chosen for further investigation.
Untreated parental Ramos cells were morphologically normal after
acridine orange staining (Fig.
7A, upper left panel),
while
the untreated, EBV-infected Ramos (Ramos-EBV) culture exhibited
significant numbers of cell aggregates, reminiscent of the phenotype
induced by infection of primary B cells with EBV (Fig.
7A, lower
left
panel). Upon treatment with cisplatin, nearly all parental
Ramos cells
appeared apoptotic (Fig.
7A, upper right panel). In
the Ramos-EBV
culture, although there were a number of cells showing
nuclear
condensation characteristic of apoptosis (Fig.
7A, lower
right panel),
occasional single cells and the majority of cells
within the aggregates
appeared morphologically normal (Fig.
7A,
lower right panel). This
suggested that infection of Ramos with
EBV afforded protection against
cisplatin-induced apoptosis.
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FIG. 7.
De novo infection of Ramos cells with B95.8 EBV confers
resistance to cisplatin-induced apoptosis. (A) Cells were harvested and
stained with acridine orange before (left) or 16 h after (right)
incubation with cisplatin. Note the aggregation of cells in the
infected Ramos culture which is characteristic of EBV infection of B
cells (lower left). While uninfected Ramos cells treated for 16 h
with cisplatin (upper right) are almost all apoptotic, cells within the
aggregates in the infected cells appear morphologically normal (lower
right, arrowheads), with occasional single apoptotic cells (arrows).
(B) Confocal microscopy after dual staining of parental Ramos (upper
panels) and infected Ramos (lower panels) cells with TUNEL for
apoptosis (green) and EBNA-LP as a marker of EBV gene expression (red).
The majority of parental, uninfected Ramos cells are TUNEL positive
after treatment with cisplatin (upper right). In the Ramos-EBV cells
treated with cisplatin, there was no colocalization of TUNEL and
EBNA-LP staining (merged image, lower right panels). The split image
clearly shows that cellular TUNEL and EBNA-LP staining are mutually
exclusive and that the effect was not simply due to a masking of one
fluorescence with the other.
|
|
Figure
7B shows the result of double staining infected and uninfected
cells for apoptosis using TUNEL (green) and for the
presence of EBV
with an antibody directed against EBNA-LP, an
early marker of EBV
infection (red). Strikingly, the majority
of EBNA-LP staining in
untreated Ramos-EBV cells was found in
cells within the aggregates
(Fig.
7B, lower left panel), suggesting
that the aggregation observed
in acridine orange-stained Ramos-EBV
cells was indeed a consequence of
viral infection. Although there
was a very low level of apoptosis in
uninfected Ramos cells (Fig.
7B, upper left panel), after 16 h of
treatment with cisplatin,
there was a 14-fold increase in
TUNEL-positive cells (Fig.
7B,
upper right panel, and data not shown).
In the Ramos-EBV culture,
TUNEL positivity increased only fourfold
after treatment and was
detected only in EBV-negative cells;
conversely, EBV-positive
cells were always negative for TUNEL staining
(Fig.
7B, lower
right panels, merged and split images). This pattern of
staining
was also evident in cells not localized to aggregates (data
not
shown). The EBV-positive cell aggregates appeared similar in
untreated
and treated Ramos-EBV (Fig.
7B, compare lower panels).
The mutually
exclusive pattern of EBNA-LP and TUNEL staining clearly
demonstrates
that the presence of EBV can protect against
genotoxin-induced
apoptosis in these
cells.
EBV does not protect against apoptosis per se.
The data shown
in Fig. 8 again demonstrate that EBV does
not protect from the consequences of DNA damage in all B cells. TUNEL analysis performed here confirmed our previous observations that LCLs
may die quite rapidly by apoptosis in response to cisplatin (Fig. 8)
(2, 3). Although AS-LCLs express the same group of EBV genes
as the B95.8-converted BL lines, they are almost 100% TUNEL positive
24 h after treatment with cisplatin (Fig. 8, right panels). In
contrast, BL41/B95.8 cells, after a similar exposure to the drug,
remain completely negative for TUNEL staining (Fig. 8, middle panels).
In the p53-positive setting of LCLs, EBV does not suppress apoptosis.
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FIG. 8.
EBV cannot prevent genotoxin-induced apoptosis per se.
In an independent measure of apoptosis, cells were treated with
cisplatin (10 µg/ml) before harvesting at the indicated time points
and assessed for apoptosis (y axis) using FITC-labeled
nucleotide incorporation (the TUNEL assay) and DNA content using
PI (x axis). Consistent with PARP cleavage data (Fig. 4),
BL41/B95.8 cells are protected against cisplatin-induced apoptosis
(compare middle and left columns). However, expression of the same
viral latent genes in the lymphoblastoid cell line AS-LCL (right
column) is unable to protect these cells from genotoxin-induced
apoptosis.
|
|
LCLs also traverse G2/M but subsequently die from
G1/S.
Normal human B cells stimulated by mitogens
(e.g., interleukin-4 and anti-CD40) arrest in both G1 and
G2/M when exposed to cisplatin, but LCLs treated in the
same way undergo apoptosis largely from the G1/S boundary
(2, 3). Since LCLs express the same set of EBV latent genes
as BL41/B95.8, a prediction based on the experiments described above is
that a significant number of LCLs will complete cell division after
cisplatin treatment; EBV should be able to override the
G2/M checkpoint(s). Figure 9
illustrates that this is indeed the case. Sixteen hours after treatment
with cisplatin, a BrdU-labeled population of AS-LCLs are able to
complete cell division and cells emerge as a labeled G1
population in a way which is almost indistinguishable from the behavior
of BL41/B95.8. However, between 16 and 24 h, the LCLs which have
completed cell division then undergo apoptosis from G1 and
so produce a significant sub-G1 peak in the flow cytometric analysis of the BrdU-labeled and unlabeled populations (Fig. 9, bottom
panels).
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FIG. 9.
LCLs treated with cisplatin (10 µg/ml) also traverse
G2/M but subsequently die from G1/S. BrdU
labeling experiments were as described for Fig. 2. (A) Both BL41/B95.8
cells and AS-LCL cells are able to complete mitosis in the presence of
cisplatin (indicated by asterisks). (B) The appearance of cells with
G1 DNA content after electronically gating confirmed this.
However, AS-LCLs (presumably due to activation of p53 at the
G1/S transition) subsequently undergo apoptosis and exhibit
a sub-G1 distribution (B, 24h, right column).
|
|
LMP-1 expression is neither sufficient nor necessary to protect BL
cells from apoptosis or G2/M arrest induced by
genotoxins.
As outlined above, EBV LMP-1 has been reported to
protect cells from apoptosis. It has been suggested variously that this is because LMP-1 can induce the expression of antiapoptotic factors Bcl-2 (26, 42), A20 (19, 32), and Mcl-1
(56) and/or because it can mimic ligation of CD40 at the
surface of B cells (7, 30). To investigate the role of LMP-1
in the repression of the p53-independent apoptosis and/or cell cycle
arrest described here, the responses of various sublines of BL41 to
cisplatin were examined. The expression of LMP-1 in various lines
analyzed in this study is shown in Fig.
10A.
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FIG. 10.
LMP-1 is not required or necessary for protection. (A)
Western blots showing LMP-1 was not expressed in uninfected BL41 cells
(tracks 1 to 5), cells infected with P3HR1 virus (tracks 11 to 15), or
cells transfected with empty vector (tracks 26 to 30) but was expressed
at constant levels in cells infected with B95.8 virus (tracks 6 to 10)
and cells transfected with LMP-1 expression vectors, BL41/MTLM-5
(tracks 16 to 20) and BL41/MTLM-11 (tracks 21 to 25) (54).
The level of LMP-1 expression in an LCL is shown for comparison (tracks
31 to 35). The apparent lack of expression in tracks 17 and 18 resulted
from faulty transfer of protein to the nitrocellulose filter. Each set
of five lanes represents a time course over 16 h after the
addition of cisplatin. Samples were taken every 4 h. (B) Western
blots showing PARP cleavage from the same time course. BL41/MTLM-5 and
-11 cells expressed levels of LMP-1 similar to the level produced by
BL41/B95.8 and were as sensitive to cisplatin-induced apoptosis as the
empty vector control, BL41/gpt. Conversely, BL41/P3HR1 cells expressed
no LMP-1; they were protected against cisplatin-induced apoptosis.
|
|
As judged by the cleavage of PARP (Fig.
10B) and examination of cell
morphology (data not shown), two clones of BL41
which
express LMP-1
from stably maintained plasmids
are as prone to
undergo apoptosis when
treated with cisplatin as a vector-transfected
control clone and the
parental BL41 cells (Fig.
10B, compare BL41/MTLM5
and BL41/MTLM11
with BL41/gpt and with BL41 in Fig.
1A). Although
the level of LMP-1
expressed in these lines is much lower than
in LCLs, it is comparable
to that detected in BL41/B95.8 (Fig.
10A). In a parallel experiment, a
subline of BL41 converted with
the P3HR1 strain of EBV appeared to be
protected from apoptosis
as efficiently as one converted with B95.8
virus. This was confirmed
by TUNEL analysis (Fig.
11). BL41/P3HR1 cells express neither
LMP-1
nor the main viral transactivator protein, EBNA2 (see also Fig.
13). The ability of P3HR1 virus to protect as well as B95.8 was
confirmed in two Ramos sublines converted with P3HR1 virus: AW-Ramos
and EHRB-Ramos. Both of these cell lines also fail to undergo
apoptosis, as judged by PARP cleavage (Fig.
12A) and morphology
(data not shown) or arrest in G
2/M (Fig.
12B and C) after
treatment
with cisplatin. The patterns of EBNA expression (Fig.
13) validated
the various lines as
being converted with the appropriate
virus.
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FIG. 11.
The P3HR1 strain of EBV prevents apoptosis in BL41
cells, as judged by TUNEL assay. Independent confirmation that P3HR1
virus protects against genotoxin-induced apoptosis was obtained using
the TUNEL assay as described for Fig. 8. Note complete absence of TUNEL
positivity even 24 h after treatment.
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FIG. 12.
The P3HR1 strain also prevents apoptosis and allows
cell division in Ramos cells treated with cisplatin (10 µg/ml). (A) A
Western blot showed that although Ramos cells were sensitive to
cisplatin-induced apoptosis as measured by PARP cleavage, two
independent sublines of Ramos infected with the P3HR1 strain of EBV
(AW- and EHRB-Ramos) were protected over the same 16-h time course. (B)
After exposure to cisplatin, Ramos cells fail to complete mitosis
[compare 16h Ramos (+ cisplatin) and ( cisplatin)], whereas the
P3HR1 EBV-infected EHRB-Ramos cell line is able to complete mitosis
[EHRB (+ cisplatin); the asterisk indicates the labeled G1 cells].
(C) Cell cycle profiles of BrdU-labeled populations were electronically
gated as described for Fig. 2.
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FIG. 13.
Western blots of sublines to validate the viral strains
in the latently infected cells. The B95.8 strain of EBV expresses the
nuclear antigens EBNA1 and EBNA2, and these were detected in both
BL41/B95.8 and an LCL established with this virus (tracks 2 and 4, respectively). P3HR1 does not express EBNA2 due to a genomic deletion;
the presence of virus was instead confirmed by immunoblotting infected
BL41 and Ramos BL cell lines with human serum which detected EBNA1
(tracks 3, 6, and 7). It should be noted that an EBNA1 protein with an
electrophoretic mobility slightly faster than that from B95.8 (X) is
characteristic of a cross-reactive cellular protein recognized by the
human serum.
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|
The levels of Bcl-2 and related proteins do not change when BL41
cells undergo apoptosis, and they are not predictive of the outcome of
drug treatment.
It has been shown that the stoichiometry of
interactions between Bcl-2 family members can determine whether cells
survive or die following apoptotic stimuli (50). Moreover,
expression of latent EBV genes can in certain circumstances induce the
expression of Bcl-2, Mcl-1, and A20 (see above). To determine whether
the sensitivity to cisplatin of BL41 and the two converted lines
(BL41/B95.8 and BL41/P3HR1) was related to the level of Bcl-2,
Bcl-XL, Bax, or Mcl-1 that each expresses, a series of
Western blot analyses were performed. The results revealed that there
was no significant difference in the levels of Bcl-2,
Bcl-XL, or Bax, either in comparison of the parental BL41
with the converted cells or following treatment of each with cisplatin
(Fig. 14). A significant reduction in
the level of Mcl-1 was detected in the converted lines relative to the
parental BL41, and consistently we saw a modest depletion of Mcl-1
protein in all three lines following treatment with cisplatin (Fig.
14). Since a reduction occurred in the resistant converted cells to a
similar degree as in the parental line, this phenomenon is clearly not
directly linked to apoptosis. We conclude that the levels of these
Bcl-2-related proteins was not predictive of the outcome of drug
treatment. However, it should be noted that it was not possible to
measure the levels of A20 protein because no suitable antibody was
available.
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FIG. 14.
Western blots showing the expression of Bcl-2 family
proteins. BL41 and BL41 cell lines infected with the B95.8 or P3HR1
strain of EBV were exposed to cisplatin (10 µg/ml) for 16 h, and
levels of Bcl-2 and related proteins was determined from samples taken
at 4-h intervals. Levels of antiapoptotic Bcl-2 and Bcl-XL
and the proapoptotic protein Bax are similar and remain unchanged in
all three cell lines during the experiment. The levels of the
antiapoptotic protein Mcl-1 decreased slightly in all three cell
lines.
|
|
| |
DISCUSSION |
In this study, we have demonstrated that in at least two Burkitt
lymphoma-derived cell line genotoxins activate a G2/M
checkpoint which prevents the completion of cell division and triggers
the apoptosis program in a p53-independent manner. We showed for the first time that the activation of this checkpointor the downstream signalling pathway to the apoptosis molecular machineryis
specifically suppressed by expression of a subset of EBV latent gene
products (see below). The cell lines which were investigated in detail (BL41 and Ramos) both express a single mutant p53 allele which is
completely inactive for the wild-type functions of transactivation and
apoptosis induction (2). Moreover, once it was clearly established that these cells underwent apoptosis from
G2/M in response to cisplatin and that sublines latently
infected with EBV completed cell division, it was possible to determine
whether EBV could disrupt the checkpoint in p53-positive B cells.
Although the checkpoint was actually revealed in a setting which is
null for wild-type p53 function, we now believe that it can be
activated in a p53-positive setting and that here also it is suppressed by EBV. Mitogen-stimulated normal cells arrest in both G1
and G2/M in response to genotoxins such as cisplatin
(2). In contrast, B-LCLs which were immortalized by EBV
failed to arrest in G2/M, suggesting that again EBV
suppressed a checkpoint (Fig. 9). However, in the LCLs, because the p53
checkpoint is retained and therefore apoptosis occurs largely from
G1/S, the suppression in this setting is revealed only by
the multiparameter flow cytometry used here.
The nature of the p53-independent pathway which signals from damaged
DNA to the apoptosis program has not been addressed in this study.
However, the recent demonstration that cisplatin can induce two
parallel death response pathways, one dependent on p53 and the other
dependent on its close relative p73, merits consideration. Several
reports (1, 21, 58) indicate that although p53 and p73 are
regulated by distinct mechanisms, both are involved in DNA damage
responses. The activation of p73 involves the c-Abl tyrosine kinase and
also requires a functional DNA mismatch repair system. It is possible
this pathway is activated in the p53-independent responses reported
here for BL41 and Ramos and that it may be therefore a specific target
of EBV. The status of p73, c-Abl, and the mismatch repair capability of
these cell lines is currently under investigation. However, it should
be noted that mutant p53 proteins, similar to those found in BL41 and
Ramos, often bind to and inactivate p73 (12). A third
parallel pathway cannot be discounted.
The effect of EBV infection in these cells is remarkably robust. For
more than 24 h after treatment with highly damaging doses of each
of four different genotoxic drugs, EBV gene expression appears to
protect nearly 100% of cells from apoptotic death and allow the
completion of mitosis and cytokinesis. This phenotype was seen in both
B95.8- and P3HR1-infected cells from a variety of different
laboratories. Furthermore, we have clearly shown that the protection by
EBV was evident 3 days after infecting Ramos cells with the B95.8
strain of EBV (Fig. 7). These experiments convincingly show that EBV,
and not selection in culture, is responsible for the resistant phenotype.
Since the expression of all known latent EBV genes in LCLs does not
prevent apoptosis mediated by wild-type p53, we suggest that it is
unlikely that the apoptosis machinery itself is being inhibited in
these BL cells. The data are more consistent with some EBV gene
product(s) interfering with a G2 phase or mitotic checkpoint which here is linked to a default apoptosis pathway. The
target cellular molecules in this system are not known, although the
Chk1/Cdc25C/Cdc2 pathway is an attractive candidate. Since P3HR1 virus
protects as well as B95.8, several EBV genes can be eliminated as viral
effectors (Table 1). EBNA2, LMP-2, and full-length EBNA-LP cannot be
necessary, however; perhaps most surprising was the demonstration that
LMP-1, the best-characterized antiapoptotic latent EBV protein, has no
role in the protection shown here. Again this is consistent with EBV
modulating cell cycle regulation rather than execution of the
apoptosis program. In addition to EBNA1 and the EBNA3 family of
proteins (3A, B, and C), the small untranslated EBV-encoded RNAs
and the orphan BamHI region A rightward transcripts require
investigation. One or a combination of these viral products has a
previously unknown and unsuspected but profound effect on B-cell
biology. Our recent observation that EBNA3C can interfere with a
mitotic checkpoint may prove to be relevant in this context
(44).
The development of BL is multifactorial and very complex, and the
precise role played by EBV is still controversial (34, 47).
It is therefore difficult and perhaps premature to speculate on the
role of EBV and the G2/M checkpoint in BL tumorigenesis. However, this study has highlighted an unforeseen mechanism through which EBV can modulate a cell cycle checkpoint or specifically inhibit
the activity of downstream effectors. Such a checkpoint must be
important for monitoring the timing and fidelity of cell division, and
its modulation could therefore be very important in EBV-associated
growth transformation of B cells. EBV should prove to be a unique tool
for dissecting this aspect of cell proliferation and survival.
| |
ACKNOWLEDGMENTS |
We thank M. Rowe (Cardiff), G. Klein (Stockholm), C. Gregory
(Nottingham), and Kirsten Knox (Oxford) for cell lines and G. J. Inman for helpful comments during preparation of the manuscript.
We are very grateful to the MRC for financial support through a Ph.D.
studentship to M.W.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Section of
Virology and Cell Biology, and Ludwig Institute for Cancer Research,
Imperial College of Science Technology and Medicine, St. Mary's
Campus, Norfolk Place, London W2 1PG, United Kingdom. Phone: 0171 724 5522. Fax: 0171 724 8586. E-mail: m.allday{at}ic.ac.uk.
| |
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Molecular and Cellular Biology, February 2000, p. 1344-1360, Vol. 20, No. 4
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
