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Journal of Virology, September 2001, p. 8556-8568, Vol. 75, No. 18
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.18.8556-8568.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
An Epstein-Barr Virus Isolated from a Lymphoblastoid Cell Line
Has a 16-Kilobase-Pair Deletion Which Includes gp350 and the
Epstein-Barr Virus Nuclear Antigen 3A
Wonkeun
Lee,1,*
Yoon-Ha
Hwang,1
Suk-Kyeong
Lee,2
Chitra
Subramanian,3 and
Erle
S.
Robertson3,*
Department of Biological Sciences, Myongji University,
Yongin Kyunggi-do,1 and Institute of
Immunobiology, Catholic Research Institutes of Medical Sciences,
Catholic University, Seoul,2 Korea, and
Department of Microbiology and Immunology and Comprehensive
Cancer and Geriatrics Center, University of Michigan Medical School,
Ann Arbor, Michigan 48109-09343
Received 24 May 2001/Accepted 13 June 2001
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ABSTRACT |
Epstein-Barr virus (EBV) is associated with human
cancers, including nasopharyngeal carcinoma, Burkitt's lymphoma,
gastric carcinoma and, somewhat controversially, breast
carcinoma. EBV infects and efficiently transforms human primary B
lymphocytes in vitro. A number of EBV-encoded genes are critical for
EBV-mediated transformation of human B lymphocytes. In this study we
show that an EBV-infected lymphoblastoid cell line obtained from the
spontaneous outgrowth of B cells from a leukemia patient contains a
deletion, which involves a region of approximately 16 kbp. This
deletion encodes major EBV genes involved in both infection and
transformation of human primary B lymphocytes and includes the
glycoprotein gp350, the entire open reading frame of EBNA3A, and the
amino-terminal region of EBNA3B. A fusion protein created by this
deletion, which lies between the BMRF1 early antigen and the EBNA3B
latent antigen, is truncated immediately downstream of the junction 21 amino acids into the region of the EBNA3B sequence, which is out of
frame with respect to the EBNA3B protein sequence, and indicates that EBNA3B is not expressed. The fusion is from EBV coordinate 80299 within
the BMRF1 sequence to coordinate 90998 in the EBNA3B sequence. Additionally, we have shown that there is no detectable induction in
viral replication observed when SNU-265 is treated with phorbol esters,
and no transformants were detected when supernatant is used to infect
primary B lymphocytes after 8 weeks in culture. Therefore, we have
identified an EBV genome with a major deletion in critical genes
involved in mediating EBV infection and the transformation of human
primary B lymphocytes that is incompetent for replication of this
naturally occurring EBV isolate.
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INTRODUCTION |
Epstein-Barr virus (EBV),
a ubiquitous human gammaherpesvirus, has unique properties in
activating resting B lymphocytes and transforming them into
continuously proliferating lymphoblastoid cell lines (LCLs) (33,
35, 50). In these transformed cells, which resemble a phenotype
of activated B cells by cognate antigen binding to the surface receptor
(1, 34; A. B. Rickinson, Editorial, N. Engl.
J. Med. 388:1461-1463, 1998), the episomes reside in
the nuclei of cells as a latent episome and are actively engaged in
continuous expression of a number of viral latent genes, thereby
inducing and maintaining proliferation of transformed cells while
presumably preventing them from terminal differentiation and apoptosis
(4). These latent gene products include six nuclear antigens (EBNAs), three membrane antigens (LMPs), two small
nonpolyadenylated RNAs (EBERs), and the BARF0 RNAs (9, 15, 20,
27, 28, 33, 40-42, 63-65). The continuous expression of these
genes in LCLs suggests that many of them may play important roles not
only in the initiation of the transforming process but also in the maintenance of the proliferative state of the transformed LCLs (33, 37, 51). In fact, biochemical and molecular genetic analyses involving recombinant EBV with mutations in the latent genes
and further testing the ability of the resulting recombinant virus to
transform primary B cells have demonstrated that EBNA1, EBNA2, EBNA3A,
EBNA3C, EBNA-LP, and LMP1 are critical, whereas LMP2A and -2B, the
EBERs, and EBNA3B are dispensable for EBV-induced B-cell transformation
in vitro (9, 15, 19, 28, 33, 39, 41, 42, 63-65).
EBNA-1 may function in both the replication of viral episomes and the
stable segregation and maintenance of viral episomes into daughter
cells (68, 69). EBNA2 is a powerful transactivator of
viral and cellular gene transcription (8, 67). This
EBNA2-mediated transactivation drives the continuous expression of the
EBV major latent genes and upregulation of cellular genes related to
cell division and proliferation (5, 33, 35, 66, 67). LMP1 is essential for transformation of B lymphocytes and functions as an
activated TNFR/CD40-like signaling receptor, constitutively transmitting activation signals in a ligand-independent manner (27, 44). In addition, blocking expression of LMP1 in LCLs by incubating with LMP1 antisense oligomers leads to apoptosis (4, 33). Moreover, cells transformed with a conditional
EBV mutant for EBNA2 fused to an estrogen receptor were growth arrested in the absence of estrogen (31, 32). Of these essential
genes, EBNA2 and LMP1 have been shown to be necessary for the
initiation and maintenance of continuous LCL growth (9,
27). Further genetic analysis, which truncated EBNA3A and -3C
proteins at amino acids 302 and 365, respectively, resulted in null
recombinant EBV in terms of their ability to transform B lymphocytes
(65). Surprisingly, a separate report suggested that
EBNA3A is not required for maintenance of the transformed phenotype
(30).
Mutants of EBV have been previously isolated containing deletions in
essential genes required for virus infection, replication and
transformation. Two of the strains, the P3HR-1 and Daudi strains, contain deletions in the critical transforming genes EBNALP and EBNA2
(17, 36, 57, 60, 61, 71, 73). The B95-8 strain has a
deletion of approximately 12 kb of viral DNA adjacent to the viral
encoded DNA polymerase and gp110 open reading frames (ORFs) but is
fully functional in terms of its ability to infect, replicate, and
transform B lymphocytes (2, 13). The Raji strain
has been characterized and has been shown to have two major deletions
(3, 13, 26, 72): one in a region adjacent to the BARF1
oncogene and the BALF2 reading frame that encodes the single-stranded
DNA-binding protein and another which lies within the EBNA3C gene
critical for B-lymphocyte transformation (13). This strain
is incompetent for transformation in addition to genome replication
(12). However, it can be rescued for replication by
providing the BALF2 cDNA in trans and also for
transformation by rescuing the EBNA3C deletion by recombination, which
incorporates the wild-type EBNA3C gene from an overlapping genomic DNA
fragment (12, 54). This recombination event renders the
resulting virus competent for B-lymphocyte transformation
(54).
The two distinct types of EBV, I and II, share high sequence homology
throughout their genomes, except for regions encoding EBNA2, -3A, -3B,
and -3C, and also show small but type-related differences in EBER genes
(2, 17, 59, 62, 70). Type-related genes easily
characterized at the nucleotide or protein level have provided a means
of type determination for EBV isolates. Here we report the
identification of an EBV strain infecting a spontaneously derived LCL
from a leukemia patient, with a deletion of a portion of its genome,
which includes lytic and latent cycle-associated genes. Some of these
genes, the gp350 glycoprotein, and the EBNA3A latent nuclear
antigen are important for infection and transformation of human primary
B lymphocytes. The identification of such an LCL, along with
previous studies with recombinant EBV, suggests that EBNA3A
may be critical but not essential in the early stages of
transformation and may also be dispensable for maintenance of the
transformation phenotype.
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MATERIALS AND METHODS |
Plasmids and cosmids.
Plasmids pBS-EcoG2 and pBS-EcoF were
constructed by cloning the B95-8 EcoRI G2 or F fragment
derived from the EBV SalI C fragment into the
EcoRI site of pBluescript SK(+), respectively. These constructs were used as a source of EcoRI G2 and F fragments
as probes in Southern blot hybridization and analysis. The
SalI-C cosmid was constructed by ligating the
SalI C fragment of EBV into the SalI site of
pDVCosA2 and packaging using the Stratagene Lambda gold packaging system.
Cells and cell culture.
B95-8 is a marmoset B-cell line
immortalized by type I EBV (2). AG876 is a
Burkitt's lymphoma (BL) cell line derived from an African BL
and harbors the type 2 EBV (11, 17, 48, 49). BJAB is an
EBV-negative BL cell line (49, 50, 52). SNU-265 and
SNU-1103 LCLs are spontaneous EBV-transformed B-lymphocyte cell lines
derived from non-EBV-related cancer patients and were described
previously (10). All cell lines except SNU-265 were grown
and maintained in RPMI 1640 medium (Gibco-BRL) with supplements of 2 mM
L-glutamine, 5 µg of gentamicin (Gemini Bio-Products) per
ml, and 10% heat-inactivated fetal bovine serum. SNU-265 was also
grown in essentially the same medium described above with a 20%
serum concentration.
Induction and PCR analysis of virus progeny.
To determine
whether SNU-265 is competent for virus replication and can produce
progeny, we collected 5 million exponentially growing cells, which were
centrifuged and resuspended in 5 ml of fresh medium containing phorbol
ester at a concentration of 20 ng/ml of medium. Cells were further
incubated for 4 days at 37°C with 5% CO2. The
supernatant was then collected, and viral particles were spun down at
15,000 rpm for 20 min. The pellet was resuspended in 25 µl of 0.2×
phosphate-buffered saline (PBS), heated to 95°C for 15 min, and then
switched to 56°C for 1 h with proteinase K treatment (10 mg/ml). The enzyme was then killed by treatment at 95°C for 30 min. A
5-µl portion of virus lysate was used for PCR amplification of the
EBNA3C, region for 40 cycles, and standard protocols were followed
using primers that can detect the type 1 or type 2 differences within
the EBNA3C gene.
Southern blot analysis.
DNA was prepared from 10 million
cells using a modified Hirt fractionation method (18, 58).
Briefly, cells were washed once in PBS and lysed in 2 ml of lysis
buffer (10 mM Tris-HCl, pH 7.5; 10 mM EDTA; 0.6% sodium dodecyl
sulfate [SDS]). NaCl was added to a final concentration of 1.0 M, and
the cell lysate was incubated overnight at 4°C to selectively
precipitate high-molecular-weight, bulky nuclear DNA, which was
then removed by a high-speed centrifugation (12,000 rpm) for 20 min at
4°C. DNA in the resulting Hirt supernatant was then extracted with
phenol-chloroform (1:1) and chloroform-isoamyl alcohol (24:1),
precipitated by adding 2 volumes of absolute ethanol, dried, and
resuspended in 100 µl of Tris-EDTA (pH 7.5).
For Southern blotting, 10 µg of each DNA sample was digested to
completion with EcoRI or BamHI and then 5-µg
aliquots were fractionated by electrophoresis through two 0.7%
ME-agarose gels (53). DNA in each gel was blotted
onto a nylon membrane (GeneScreen Plus; NEN-Dupont), which was
hybridized with 32P-labeled probes prepared from either the
HindIII E or the EcoRI G2 plus F DNA fragments of
B95-8 EBV type I DNA. DNA labeling was done using
[
-32P]dCTP (ICN) and the Prime-It II random labeling
kit (Stratagene) according to the protocol provided by the
manufacturer. The nylon membranes were washed using stringent
conditions and exposed to X-ray film. For reprobing, the membranes were
stripped as described previously and further hybridized with either the
4.0-kb KpnI/KpnI or the 1.6-kb
KpnI/EcoRI fragment derived from EcoRI
G2 (2).
PCR and sequencing analyses.
For amplification of sequences
encompassing the SNU-265 deletion-specific junction, PCR was carried
out using a pair of primers, 265DF1 (5'-[79453 to 79472]-3')
and 265DR1 (5'-[97457 to 97438]-31), designed to target
sequences flanking the junction. The reaction mixtures of a final
volume of 50 µl were set up in 0.25-ml microtubes and contained 0.1 to 0.25 µg of Hirt-fractionated cell DNA, a 0.2 mM concentration of
each deoxynucleoside triphosphate, 100 pmol of each primer, 20 mM
Tris-HCl (pH 8.4), 50 mM KCl, 1.5 mM MgCl2 and 0.5 µl of
recombinant Taq polymerase. The tubes were subjected to
heating at 95°C for 5 min and subsequently to 40 cycles, each
composed of 95°C for 1 min, 56°C for 1 min, and 72°C for 2 min,
followed by further incubation at 72°C for 10 min, in a PTC-100
programmable thermal cycler (MJ Research, Inc.). Next, 5-µl aliquots
of PCR products were assayed by electrophoresis on a 2.0% ME-agarose
gel containing ethidium bromide (56). The PCR product was
expected to have a BamHI site 85 bp away from its 5' end and
an EcoRI site at the very 3' end that were introduced at the
end of the EBV-specific primer sequences in the 265DR1 primer. For
sequencing analysis, amplified DNA was digested with EcoRI
and BamHI and ligated to the corresponding sites of
pBluescript SK(+) to yield pBS-265D. Sequencing was carried out using
T7 primer and the Thermo Sequenase radiolabeled (33P)
terminator cycle sequencing kit (Amersham Life Sciences). Labeled products were then resolved on a 6% sequencing gel. The gel was dried
on a sheet of Whatman 3 MM filter paper and subjected to autoradiography at 80°C. Based on the sequencing data, an
NcoI site was present in the insert, which was confirmed to
be unique in the plasmid pBS-265D. To get deletion-junction sequences
from the T7 primer, a deletion derivative,
p265D-dNcoI/EcoRI, was made from pBS-265D by deleting its
sequences between EcoRI and NcoI, blunting ends,
and self-ligation. The nucleotide sequences obtained were analyzed by
the Editseq program in DNASTAR and searched against the entire EBV type
1 sequence.
Western blot analysis.
Cells (2 × 106)
were harvested, washed with Dulbecco PBS (Gibco-BRL), and lysed in 400 µl of SDS loading buffer (114 mM Tris-HCl, pH 6.8; 3.7% SDS; 18.2%
glycerol; 1.31 M 2-mercaptoethanol; 0.045% bromophenol blue). A
total of 100 µl of this lysate was fractionated on an SDS-8%
polyacrylamide gel electrophoresis gel, and the fractions were
transferred to a 0.45-µm (pore-size) nitrocellulose
membrane. The membrane was probed with a human polyclonal serum capable of detecting the repertoire of EBNA proteins expressed by EBV during
latent infection, the S12 monoclonal antibody for the detection of
LMP1, and the A10 monoclonal antibody for the detection of EBNA3C
(6, 43). The membrane was stripped as described previously and washed extensively in PBS with Tween 20 before being probed with
the subsequent antibodies. Signals were detected by chemiluminescence using standard procedures (6).
Transformation of primary B lymphocytes by EBV.
Virus
supernatants from B95-8 derived LCL and SNU-265 were filtered
through a 0.45-µm-pore-size sterile filter. Primary B lymphocytes were harvested by rosetting from peripheral blood monocytic
cells using a Lymphoprep gradient. The enriched B-lymphocyte population was washed and infected with virus supernatant at 5 million
B lymphocytes per infection and plated at 50,000 cells in 150 µl of
complete medium per well in a 96-well tissue culture plate. Phorbol
ester-induced viral supernatants from B95-8 derived LCL and SNU-265
were used for the infections, and supernatant from BJAB-treated cells
was used as a negative control. All 96-well plates were incubated at
36°C with 5% CO2 for 4 to 8 weeks. The plates were
treated once after 8 days of incubation with another 100 µl of
complete medium.
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RESULTS |
PCR analyses suggest that the EBV genome maintained in the SNU-265
LCL contains a deletion in the region of EBNA3A and its adjacent ORFs
encoding latent and lytic genes.
Two distinct types of EBV strains
maintain characteristic sequence differences in four EBV nuclear
antigen genes (EBNA2, -3A, -3B, and -3C) (33, 59). The
specific types of EBV isolated from patients can be determined by
exploiting such type-specific differences in these EBNA genes either at
the nucleotide level or at the amino acid level. During PCR analyses of
a panel of EBV isolates from spontaneous LCLs derived from cancer
patients to determine their genotypes, we found an EBV isolate,
SNU-265, which was consistently negative for amplification of the
EBNA3A gene despite positive amplifications for the EBNA2, -3B, and -3C genes (see Fig. 1 for the positions of
the EBNA genes on the EBV genome). A representative of such
PCR-mediated genotyping analyses using primers specific for each of
type-distinct EBNA genes is shown in Fig.
2. All of the typing primers
employed
E2-1 and E2-2 for the EBNA2 gene, A1 and A2 for the EBNA3A
gene, B1 and B2 for the EBNA3B gene, and C1 and C2 for the EBNA3C gene
(Table 1)were derived from sequences
which flank type-distinct regions in each EBNA gene and are shown to be
conserved in both type 1 and type 2 viruses. As expected, B95-8, the
prototypic type 1 strain, and SNU-1103, a type 1 strain isolated from a
leukemia patient, yielded type 1-specific bands, respectively. AG876,
the prototypic type 2 strain, yielded the type 2 allelic bands for all
four EBNA genes analyzed. However, SNU-265 failed to give any PCR
product (using the specific primer sets A1 and A2 for the EBNA3A gene),
although it gave type 1-allelic bands for other EBNA genes (Fig. 2,
compare panels A to D). The A1 and A2 specific amplification is shown in Fig. 2C.
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FIG. 1.
Schematic illustration showing a linear EBV genome with
the relative positions of the EBNA2, -3A, -3B, and -3C and gp350 genes.
These genes were analyzed by PCR to determine the genotypes and
deletion ends of the SNU-265 genome. The respective gene-specific
primers employed are indicated over each ORF (denoted by open bars) by
a combination of names and arrowheads. Vertical lines and filled bars
indicate the BamHI recognition sites and the terminal
repeats, respectively. Also shown are the replication origin of viral
episome, OriP, and the position of the EBNA1 and LMP1 genes (2,
13, 14).
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FIG. 2.
PCR analyses of the EBNA2, -3A, -3B, and -3C genes in
SNU-265 to determine the allelic types of each of these EBNA genes.
Aliquots of cell DNA samples obtained from SNU-265, as well as control
DNAs from B95-8, AG986, SNU-1103, and BJAB, were subjected to 40 cycles of PCR amplication, using primers that were specific for EBNA2
(E2-1-E2-2) (A), EBNA3B (B1-B2) (B), EBNA3A (A1-A2) (C), and EBNA3C
(C1-C2) (D). For the primer sequences, see Table 1. Aliquots of PCR
products were resolved on a 2.5% ME-agarose gel and visualized by
ethidium bromide staining. Note that the SNU-265 genome is type 1 for
EBNA2, -3B, and -3C and has no signal for the EBNA3A gene compared to
the prototypic B95-8 type I genome and the AG876 prototypic type 2 genome. BJAB was used as an EBV-negative control in this assay.
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One possibility for such a failure is that there could be sequence
variations in the EBNA3A primer binding sites in SNU-265,
thereby
preventing the primers from engaging in efficient priming.
To address
this possibility, we prepared another set of EBNA3A-specific
primers
(A3 and A5, Table
1; see also Fig.
1), which flank the
same EBNA3A
type-specific region, as do the EBNA3A typing primers,
but would
target different type-conserved sequences outside those
by the
latter primer set. Amplifications with the new EBNA3A primers
resulted
in expected 378-bp type 1 and 350-bp type 2 bands from
B95-8 and AG876,
respectively, but once again failed to amplify
SNU-265 (Fig.
3A and Table
1). Different combinations
of these
primers, such as A1-A5 and A3-A2, did give expected PCR
products
from B95-8 and AG876 but resulted in no bands with SNU-265
(data
not shown), providing further support for the view that the
failure
in the EBNA3A amplification may be due to the deletion of the
gene rather than to sequence alterations in SNU-265.
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FIG. 3.
Determination of the sensitivity of the PCR analysis in
the detection of the EBNA3A gene. To estimate sensitivity levels of our
PCR method, 104 IB4 cells, which contained four integrated
EBV genomes per cell, were serially diluted with 104 BJAB
cells, an EBV-negative BL cell line, and subjected to PCR
amplification. An aliquot of each dilution was amplified at the same
time to determine the approximate number of copies of EBV genomes that
can be detected using this primer set for EBNA3A. (A) Amplified
products were separated on a 2.5% ME-agarose gel and visualized by
ethidium bromide staining. (B) This gel was then transferred to a nylon
membrane and Southern blotted using an EcoRI K probe for the
EBNA3A gene. Signals were visualized by exposure to X-ray film. By
Southern blot, a weak signal was seen in the dilution of
10 4, suggesting that approximately four copies of the
genome can be detected by this PCR analysis.
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IB4 cells have four integrated EBV genomes per cell and have been used
as a copy control for the EBV genome. To estimate the
sensitivity of
our PCR analysis, we then made serial 10-fold dilutions
of
10
4 IB4 cells with the same number of BJAB cells, and DNA
preparations
made from the undiluted or diluted IB4 cells were used as
templates
in the EBNA3A PCR using A3 and A5 primers. A faint signal
where
a single IB4 cell out of the background of 10
4 BJAB
cells was detected under our experimental conditions, which
represents
four copies of EBV out of 10
4 cells (Fig.
3A showing
ethidium bromide staining). The signal
for 10 IB4 cells, which
represents 40 copies of the genomes in
DNA lysate from 10
4
cells, however, is clearly seen. The blot was then transferred
to
GeneScreen nylon membrane and probed for the
EcoRI K
fragment
of EBV, which includes EBNA3A. As expected, the specific band
was detected representing the EBNA3A signal (Fig.
3B). Thus, these
results suggest that there is a possible deletion of the EBNA3A
gene
itself rather than inefficiency of the EBNA3A PCR
amplification.
To examine the scope of the possible internal deletion in SNU-265, we
expanded our PCR analyses to the regions immediately
upstream or
downstream of the EBNA3A gene, such as those encoding
gp350 and the
amino terminus of EBNA3B, respectively. Amplifications
for the gp350
gene with two sets of gp350-specific primers (G2-G5
and G3-G4) resulted
in the expected 1.4-kb PCR products from B95-8
but no PCR bands from
SNU-265 (Fig.
1 and Table
1). Similar amplifications
for the EBNA3B
gene using the typing reverse primer (B2) and a
forward primer
targeting 944 bp (B5) or 514 bp (B7) upstream of
the B1 binding site
gave rise to PCR bands of expected sizes from
B95-8 but no signal from
SNU-265 (Fig.
1 and Table
1). Taken
together, the PCR data were most
consistent with the possibility
that SNU-265 might have a substantial
deletion of its genome,
including not only the EBNA3A gene but also its
neighboring genes
such as gp350 and the amino-terminal region of the
EBNA3B gene,
with respect to the B95-8 prototypic type 1
virus.
Southern blot analyses confirmed a large deletion in SNU-265
localized between BamHI M and E regions relative to the
B95-8 genome.
To explore and confirm possible deletions of the
EBNA3A gene and other adjacent genes in SNU-265, we carried out
Southern blot analyses, using two nonoverlapping probes which were
derived from the B95-8 EBV SalI C fragment (Fig.
4A). The two probes, designated
EcoRI G2+F and HindIII E, consisting of
either an equimolar mixture of the EcoRI G2 and F fragments
or the HindIII E fragment, respectively, allowed us to
screen a 26.3-kb contiguous stretch (B95-8 positions 76596 to 102891)
of the EBV genome (2) except for a small gap between the
two probes representing the first 400 bp of EcoRI N. The
regions covered by the probes thus contain not only the EBNA3 family of
genes but also a number of ORFs involved in the lytic replication
cycle, such as BLLF1a and -1b (gp350/220), BMRF1, and BSLF1. Cell DNA
preparations enriched for EBV episomes were made from SNU-265,
SNU-1103, B95-8, and BJAB cells by Hirt fractionation and were used to
prepare two duplicate GeneScreen nylon membranes (NEN-Dupont). Each
filter contained pairs of 5 µg of each cell DNA preparation per lane,
which had been digested with EcoRI or BamHI,
respectively, and fractionated through a 0.7% agarose gel. The filters
were then hybridized with the 32P-labeled EcoRI
G2+F or HindIII E probe and were processed for autoradiography (Fig. 4). Results obtained with the
Hind E probe detected all expected bands for
EcoRI fragments N, M, K, and B and also those for
BamHI fragments L, E, e1, e2, e3, and Z from B95-8, as
expected (Fig. 4C). The bands for EcoRI N and
BamHI e1 fragments became more prominent after a longer
period of exposure (data not shown). A faint 9.0-kb EcoRI
band was also detected at a lower intensity, suggesting partial
digestion of the EBV genomic DNA.
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FIG. 4.
Southern blotting analysis of the SNU-265 genome using
the HindIII E or EcoRI G2+F fragments as
probes to determine the position of the SNU-265 deletion. (A) Map of
the genomic region analyzed, indicating the fragments generated by
EcoRI digestion (top) and those generated by
BamHI digestion (bottom) from a region of the EBV genome
cloned as a SalI C fragment (75,601- to 105,296-bp EBV
coordinates based on the B95-8 genome). The solid lines above show the
EcoRI G2+F (76,596- to 91,421-bp) and HindE
(91,821- to 102,891-bp) fragments used as 32P-labeled
probes in panels B and C. (B) Results of Southern blot analysis of the
SNU-265 genome digested with EcoRI (R) and BamHI
(B) probed with 32P-labeled EcoRI G2+F
fragments. The fragments shown on the left of the panel are the
BamHI fragments detected and those on the right of the bands
on the panel are the EcoRI fragments. In panel B, the
leftmost panel is a shorter exposure of the blot to clearly show the
B95-8 bands used as controls in this analysis. The right panel is a
longer exposure to detect the EBV genomes in the SNU-265 and SNU-1103
with a smaller number of EBV genome copies. The closed circle in the
EcoRI digest of SNU-265 and the asterisk in the
BamHI digest of SNU-265 indicate the new fusion bands
created by the deletion, respectively. Note that the EcoRI
G2+F fragments and the BamHI L, M, O and S fragments are
missing in SNU-265. The BamHI a fragment is detected.
Analysis using the Hind E probe also shows the fusion
fragments on EcoRI and BamHI digestion,
suggesting fusion of the EcoRI B fragment and the
BamHI E fragment, respectively, with the left end in the
BamHI a region (53).
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Similar
EcoRI and
BamHI restriction patterns were
also obtained with SNU-1103, a spontaneous LCL carrying a type 1 EBV
isolate,
except for the
BamHI Z band, which ran as
2.1 kb, unlike the B95-8
counterpart of 1.7 kb. Band intensities of
SNU-1103 and SNU-265
were much weaker than those of B95-8 counterparts,
presumably
reflecting lower copy numbers of their episomal genomes
loaded
on the membrane compared to those of B95-8. Densitometric
analyses
indicated that at least 10-fold more B95-8 compared to SNU-265
or SNU-1103 copy numbers of viral episomes were represented on
the
nylon membrane. In addition, the expected bands were detected
from
SNU-1103, demonstrating the integrity of the employed probes
and
procedures and of the DNA isolation procedures used in the
Southern
analysis.
In contrast, however, with the SNU-265
EcoRI digest, the
Hind E probe detected only a single
EcoRI
band (marked by a dot),
which was slightly larger than the 30-kb
EcoRI B of B95-8 and
SNU-1103 (Fig.
4C). No other bands for
EcoRI N, M, and K fragments
were detected even upon a longer
period of exposure in the corresponding
cell line, indicating
that these three consecutive
EcoRI fragments
were deleted in
SNU-265. The absence of these
EcoRI fragments
was thus
consistent with our failure in the amplification of the
EBNA3A and the
amino-terminal sequence of gp350 from SNU-265 and
was further confirmed
by the lack of both
BamHI L and E bands
from its
BamHI digest (Fig.
4C), which overlap with these
EcoRI
fragments. The same probe, however, could detect a
1.7-kb
BamHI
Z band in B95-8 and a novel 4.4-kb
BamHI band (marked by an asterisk)
in SNU-265 (Fig.
4C).
Upon a longer exposure, the
BamHI e1 to
e3 bands could also
be detected in SNU-265, as well as in SNU-1103
(data not shown). Given
that SNU-265 yielded type 1-allele-specific
EBNA3B and -3C bands in
genotyping analyses (Fig.
2), these Southern
blot data clearly
indicated that SNU-265 lacks
EcoRI N, M, and
K fragments and
carries partially deleted
EcoRI B and
BamHI E
fragments. Thus, both the larger >30-kb
EcoRI and
4.4-kb
BamHI
bands detected in SNU-265 represent novel bands
that may be specific
for the deletion. With the
EcoRI G2+F
probe, we could readily
detect not only bands for
EcoRI
fragments F and G2 but also bands
for
BamHI fragments O, a,
M, S, and L from B95-8 and also from
SNU-1103 (Fig.
4B). The
intensities of the bands for SNU-1103
and SNU-265 were again much
weaker than those for B95-8, presumably
due to the relatively lower
copy numbers of viral genomes loaded.
However, the corresponding
signals from B95-8 are all seen in
SNU-1103 when the membrane was
exposed for a longer period to
X-ray
film.
Interestingly, probe
EcoRI G2+F detected the same larger
30-kb
EcoRI band and the 4.4-kb
BamHI bands from
SNU-265, as did
the
Hind E probe (Fig.
4, compare panels
B and C). Hence, the
detection of both bands by these two
nonoverlapping probes provides
strong evidence that these two bands
were indeed novel ones, presumably
derived from a region specific for
the SNU-265 deletion, and thus
may contain the deletion-specific
junction containing EBV DNA
from the
EcoRI G2 region and the
BamHI E region. In addition to
these bands, the probe could
detect a 1.7-kb
BamHI a band but
no bands for
BamHI M, S, and L fragments, indicating that the
novel
larger 30-kb
EcoRI and 4.4-kb
BamHI bands
were detected
by the
EcoRI G2 component of the probe. The
absence of the
BamHI
L band was consistent with our
inability to PCR amplify the gp350
gene. Taken together, the Southern
blot data indicate that SNU-265
lacks
BamHI S and L (or
EcoRI F) fragments and has the
BamHI M
(or
EcoRI G2), as well as the
BamHI E (or
EcoRI B), fragment partially
deleted. Therefore, the 5' end
of the SNU-265 deletion should
lie within
EcoRI G2 or, more
precisely, within the region overlapping
BamHI M and to the
right within the
EcoRI B, more specifically,
the
BamHI E, fragment (Fig.
4A).
To demonstrate that these novel larger 30-kb
EcoRI and
4.4-kb
BamHI bands are the deletion junction-containing
fragments carrying
a region of
BamHI M as the 5' component
of the junction and also
to more precisely map the 5' endpoint of the
deletion, we stripped
off the bound probes on both membranes and
reprobed them with
either of the two leftmost
KpnI
subfragments (Fig.
5A) of
EcoRI
G2 (the 4.0-kb
KpnI/
KpnI and
1.6-kb
KpnI/
EcoRI fragments). The
4.0-kb probe
hybridized to both novel bands (indicated on the
gel by the dot and the
asterisk), as well as the 1.7-kb
BamHI
a band in SNU-265
(Fig.
5B), whereas the 1.6-kb probe did not
give any signal with
SNU-265 though it could detect the
EcoRI
G2 and
BamHI M bands of B95-8 and SNU-1103 (Fig.
5C). These results
therefore unambiguously proved that the two novel bands are most
likely
derived from the deletion junction and indicate that the
5' end of the
SNU-265 deletion should lie within the first 1.8
kb of
BamHI
M.
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|
FIG. 5.
Southern blotting assay of SNU-265 using KpnI
subfragments of EcoRI G2 as probes to roughly map the 5'
endpoint of the deletion. (A) The nylon membrane used in Fig. 4 was
stripped and reprobed with subfragments in the EcoRI G2
region. (B) Southern blot with the 4-kb KpnI fragment
showing the BamHI O and a fragments but not BamHI
M, which migrates above BamHI O, indicated by the asterisk.
The solid circle in the EcoRI-digested lane suggests a
fusion of the EcoRI G2 and B fragments creating a larger
migrating band. (C) Southern blot using a probe of 1.6 kb from the
BamHI M fragment. As shown, no signal was seen in the
SNU-265 EcoRI- and BamHI-digested lanes. However,
the EcoRI G2 and BamHI M fragments are clearly
seen in the B95-8 and SNU-1103 control lanes. These results indicate
that the region on BamHI M is deleted in the SNU-265
genome.
|
|
The present Southern blot data obtained by the use of the two long
nonoverlapping probes clearly indicated that four
EcoRI
fragments, F, N, M, and K, have been completely deleted and that
EcoRI G2 and B have been partially deleted in SNU-265,
presumably
leading to the generation of the large 30-kbp
EcoRI fusion band.
Alternatively,
BamHI S and L
have been completely deleted and
BamHI M and E have been
partially deleted in SNU-265, thereby
giving rise to the 4.4-kb
BamHI fusion
fragment.
Analysis of the fusion junction revealed that a number of critical
EBV genes, including EBNA3A and gp350, have been deleted in
SNU-265.
To amplify the SNU-265 deletion-specific junction, we
decided to PCR amplify, clone, and sequence the junction to precisely determine the deletion and map the endpoints which created the fusion.
In designing SNU-265 deletion-specific primers, we took advantage of
the fact that this virus carried an intact BamHI a fragment
and that a portion of its EBNA3B sequence could be amplified. A forward
primer, 265DF1, was designed to target a sequence within
BamHI a, which was 85 bp away from the 3' BamHI site of BamHI a, and the EBNA3B typing reverse primer was
chosen as a reverse primer, 265RF1, with an EcoRI
recognition site at its 5' end (Fig. 6A).
Thus, while targets of these two primers would be separated by 18 kb
from each other in wild-type viruses such as B95-8, they are separated
by only 1.3 kb in an internal-deletion-containing virus such as SNU-265
(Fig. 6B). Indeed, amplifications with these primers resulted in the
approximately 1.3-kb PCR band from SNU-265 but not from B95-8 and BJAB,
an EBV-negative cell line (Fig. 6B).
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FIG. 6.
PCR analysis to amplify the SNU-265 deletion-specific
junction. (A) 265DF1 forward primer with the EBV coordinates and 265DR1
reverse primer with the EBV coordinates, according to the B95-8 strain.
An ~1.3-kb fragment was the expected PCR-amplified product, whereas
the corresponding wild-type region is approximately 16 kb and is not
amplified with the PCR analysis described here. (B) PCR-amplified
product from SNU-265 genomic DNA, with no signal in the B95-8 lane as
expected. This finding suggests that this product is specific for the
SNU-265 genome.
|
|
For sequencing analysis, the 1.3-kb PCR product was then digested with
BamHI and
EcoRI, and the resulting 1.2-kb DNA was
cloned
in the corresponding sites of pBluescript SK(+) to obtain
pBS-265D.
Restriction digestion analyses showed several enzyme
recognition
sites, which appeared to be unique in the insert and the
plasmid.
The sites included a
PstI site and an
NcoI site, presumably derived
from the BMRF1 and the EBNA3B
genes, respectively (Fig.
7B). Sequencing
analysis confirmed the presence of the EBNA3B
NcoI site,
which
was about 240 bp away from its
EcoRI end. In order to
target the
deletion junction, a construct with a deletion at the
NcoI site,
p265D-
dNcoI/EcoRI, was made from
pBS-265D by removing sequences
between
NcoI and
EcoRI and religating the blunted ends. Subsequent
sequencing
of p265D-
dNcoI/EcoRI (Fig.
7A) and analysis of determined
nucleotide sequences (Fig.
7B) revealed that the SNU-265 deletion
lies
between position 80299 in the BMRF1 gene and position 96998
in the
EBNA3B gene with respect to the EBV coordinates derived
from the B95-8
sequence. This deletion eliminates a 16.7-kbp portion
of EBV DNA. This
deletion created an out-of-frame fusion between
the BMRF1 codon 134 and
the EBNA3B codon 523, which would produce
a predicted polypeptide of
155 amino acids with the BMRF1 amino-terminal
134 amino acids and a
novel 21-amino-acid carboxyl-terminal tail
from the EBNA3B protein
sequence. These results thus confirmed
that SNU-265 lacks all genes or
ORFs located between the BMRF1
gene and EBNA3B and includes the EBNA3A
and gp350/220 genes (Table
2).
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FIG. 7.
Sequencing analysis of the SNU-265 deletion-specific
junction. The PCR-amplified product in Fig. 6 was cloned as a
BamHI and EcoRI insert into pBluescript SK(+) and
sequenced using the T7 Sequenase sequencing kit from Amersham. (A)
Sequence reaction products obtained from the signals of the
33P-labeled ends of the terminated products. The arrow on
the left shows the position of the junction from the BMRF1 reading
frame, and the remaining sequence was specific for the EBNA3B reading
frame. (B) Illustration of the fusion product created by this deletion
with the EBV coordinates shown in panel A as reference points.
|
|
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|
TABLE 2.
EBV ORFs located within the deletion of SNU-265 showing
the coordinates, encoded proteins, and their potential functions
(2, 13)
|
|
Western blot analysis indicates that the major essential latent
antigens, including the EBNA3C protein but not EBNA3A and -3B, are
expressed in SNU-265.
The Southern blot analyses described above
clearly demonstrated that SNU-265 contains a large deletion of its
genome, including the regions coding for EBNA3A and the amino-terminal
~300-amino-acid portion of EBNA3B. To determine which of the EBNA3
molecules is expressed in SNU-265, we performed Western blots for
detection of all the type 1 EBNA3 molecules. Lysates from SNU-265, as
well as control cell lines expressing the EBNA3s and an EBV-negative B
cell line, BJAB, were fractionated and transferred to nitrocellulose membranes. The results clearly demonstrate that a single band which
migrated in the region similar to that of the EBNA3 proteins was
detected by a human polyclonal serum with reactivity to the three EBNA3
proteins (Fig. 8A). The polypeptide
migrated slightly above that of the B95-8 EBNA3C band, indicating a
variation in the EBNA3 proteins in this type 1 EBV strain. The EBNA3
family members are known for their highly repetitive nature, and it is possible that the slower mobility is due to the increased size of the
repetitive region of the EBNA3C polypeptide. Since it was determined
that EBNA3A and EBNA3B were affected by the deletion, the detected band
was most likely due to EBNA3C expression. To confirm that this band is
in fact EBNA3C, the membrane was stripped and reprobed with a
monoclonal antibody to specifically detect EBNA3C (43).
Again, the results indicate that this larger migrating band was EBNA3C
(Fig. 8B). Other experiments using antibody against EBNA3A did not
reveal any signal in SNU-265 (data not shown). Therefore, these data
strongly support the previous Southern blot analyses, which
demonstrated that the EBNA3A and EBNA3B polypeptides were affected by
the deletion.
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FIG. 8.
Western blot analysis to determine the major latent gene
products expressed by the SNU-265 LCL. (A) Western blot of cell lysates
from SNU-265, two EBV-positive cell lines (B95-8 and LCL1), and an
EBV-negative control cell line using a human polyclonal serum which
recognizes all of the major EBNA proteins for the type 1 EBV strains.
The lines on the right indicates the positions of the EBNA3 proteins
migrating approximately 160 kDa and the EBNA2 and EBNA1 signals, which
are approximately 80 to 90 kDa. (B) Same blot as in panel A but
stripped and reprobed with EBNA3C-specific monoclonal antibody A10.
This blot indicates that the signal expressed in the SNU-265 cell line
is an EBNA3C-specific signal. (C) Further stripping and reprobing of
the blot with another monoclonal antibody specific for LMP1, S12, shows
the expression of LMP1 in SNU-265.
|
|
Since it was expected that EBNA3s regulate the expression of other
latent genes from the major latent promoters, we wanted
to determine if
LMP1 expression was altered. As described above,
equivalent amounts of
lysates were fractionated and transferred
to membrane and further
blotted for LMP1 signal using a monoclonal
antibody that specifically
recognizes LMP1. LMP1 was clearly expressed
in all EBV-positive cell
lines. However, we did observe a consistently
increased amount of LMP1
in SNU-265. In our Southern blot analysis
we estimated, based on
densitometric readings, that there were
approximately 10-fold more
copies of EBV genomes in B95-8 compared
to SNU-265. However, by Western
blot with equivalent amounts of
lysate loaded, approximately twofold
more LMP1 signal was consistently
seen in SNU-265. This suggests a
potential dysregulation of LMP1
expression, which may in part be due to
the absence of two major
latent proteins EBNA3A and -3B, which were
deleted from the SNU-265
genome.
Treatment of SNU-265 with phorbol esters results in no observable
induction of progeny virus.
To determine if SNU-265 with an
approximately 16-kbp deletion was capable of efficiently producing
viral progeny and transforming primary B lymphocytes, we treated
SNU-265 cells with phorbol esters, which induce EBV replication.
Supernatants from the induced cells were filtered through a
0.45-µm (pore size) filter and used for infection of fresh
human primary B lymphocytes. PCR analysis of the supernatant did not
show any detectable signal for EBV when amplified at the EBNA3C loci
(Fig. 9B). Uninduced cells were also analyzed to show that we can in fact amplify the DNA. Figure 9A shows
that EBNA3C was detected in both SNU-265 and the B95-8-derived LCL,
with both analyses done in duplicate. However, compared with the LCL,
SNU-265 had no signal of virus production after treatment with phorbol
ester after 40 cycles (Fig. 9B), suggesting that the SNU-265 did not
efficiently produce any detectable virus progeny by our PCR assay.
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FIG. 9.
PCR analysis of phorbol ester-treated SNU-265 shows no
observable induction in virus production. (A) PCR analysis from
uninduced DNA lysates prepared from SNU-265, an LCL as a positive
control, and BJAB as a negative control prepared from 50,000 cells. (B)
PCR analysis of the virus progeny produced from the same cells as in
panel A but induced with phorbol ester for 4 days. No signal was seen
with SNU-265, whereas a signal was seen from both LCL lanes.
|
|
To further test whether or not any virus progeny was produced from
SNU-265 and were able to infect primary B lymphocytes,
we used the
remaining supernatant to infect fresh primary B lymphocytes.
As
expected, no transformed LCLs were seen after 8 weeks in culture
in
three separate experiments (Table
3)
compared to the results
from the
infection with the positive control, wherein LCLs were
observed as soon
as 4 weeks in culture. These results suggest
that SNU-265 is not
capable of efficiently producing infectious
competent virus progeny.
| |
DISCUSSION |
A number of naturally occurring mutant EBV genomes with deletions
in a number of documented regions have been previously isolated from
EBV-infected cell lines (3, 17, 26, 57, 62). Some of these
deletions occur in regions encoding genes critical for the replication,
infection, and transformation of primary B lymphocytes (7, 12,
16, 22-25, 47, 55). In this study we have identified an EBV
genome infecting an LCL isolated from a leukemia patient (38) that has a deletion in a major region of the genome
encoding the gp350 gene product, the EBV glycoprotein important for
targeting the CD21 cellular receptor (45). Another major
latent gene previously known to be critical for EBV-mediated
B-lymphocyte transformation, EBNA3A, was also deleted in this
particular strain of EBV (30).
One commonly known EBV deletion mutant, lacking a 12-kb region (genomic
position 152012 EBV coordinates), is fully competent for replication
and transformation (2, 47). This B95-8 genome has been
fully sequenced, and the junction of the deletion has been identified
(47). The reading frames encoded within this deletion may be involved in the regulation of lytic reactivation of EBV
by antisense transcription, which may hinder transcription of the
essential lytic genes, including BALF2, BALF4, and BALF5. Two other
mutants, Daudi and P3HR-1, lack a major transforming region of the
genome, which encodes the EBNALP and EBNA2 (13, 14). The
deletion in Daudi and P3HR-1 renders these viruses incapable of
transforming human B lymphocytes (22, 25). However, they
can efficiently infect B lymphocytes and be stably maintained as
episomal DNA in the infected B-cell lines (34). Another
strain, Raji, contains two major deletions in its genome which render the virus incompetent for transformation, as well as for replication (16). Ooka et al. have demonstrated that this genome can
be rescued for replication through the transient or stable expression of the single-stranded DNA-binding protein encoded by the EBV ORF BALF2
(12, 46). Raji virus progeny was produced and shown to
infect B lymphocytes in vitro (12). Additionally, further experiments which utilized BALF2 stably transformed Raji cells were
able to rescue the EBNA3C deletion (54). This approach took advantage of a cosmid clone, which overlaps the region deleted in
EBNA3C recombining with the parental Raji genome to create a
recombinant Raji virus with wild-type EBNA3C. This indicated that
competent virus could be produced for the transformation of B
lymphocytes, leading to continually proliferating LCLs. However, this
process was less efficient than the well-utilized P3HR-1 system,
wherein the EBNALP and EBNA2 deletions are rescued by recombinant
events using the EcoRI A cosmid overlapping this region of
the genome (54).
Recent developments with bacterial artificial chromosomes in an F
plasmid-based system now introduce another technology for mutagenesis
of the EBV genome in Escherichia coli, which can then be
tested in B-lymphocyte transformation assays (29, 30). One
such minichromosome created picked up a mutation in the EBNA3A gene
indicating that the loss of EBNA3A expression did not affect the
maintenance of the LCLs generated in long-term growth of the culture
(30). However, other studies by Tomkinson et al. have shown that insertion of a stop codon at position 302 in the EBNA3A reading frame rendered the recombinant virus incompetent for the transformation of human B lymphocytes (65). Moreover, the
LCLs generated as coinfected cell lines did not survive long term in culture, suggesting a potential dominant-negative effect
(65). This indicates that EBNA3A is important for
EBV-mediated transformation of primary B lymphocytes. These experiments
were clearly not conclusive and further experiments will be needed to
determine the importance of EBNA3A in the transformation event. Other
developments have indicated that gp350 required for binding to the
cellular receptor CD21 can be deleted and that the resulting
recombinant virus infects and transforms primary B lymphocytes in
vitro, albeit at a lower transforming frequency compared to a
prototypic type 1 EBV (21).
Our finding, which maps a deletion in an EBV genome infecting an LCL
derived from a leukemia patient (38), is a rare example of
an EBV genome lacking major latent (as well as a lytic) EBV genes.
Other genomes identified with deletions in essential lytic and latent
genes have been identified from BLs but not from spontaneous LCLs
derived from patients. Although it is expected that spontaneous deletions may occur in the EBV genome, it is unlikely that such deletions would occur prior to infection of the B cell. In Raji cells,
for example, the virus is null for replication competency, which can be
rescued by introduction of the essential gene product, BALF2, in
trans (12, 16). Therefore, this virus would not be capable of propagating itself through replication in the host without complementation of the deleted essential lytic gene. Hence, the
deletion probably occurred postinfection, and the resulting deleted
episome was stably maintained in the infected cell.
In the case of the SNU-265 deletion, the genes are critical for
replication and transformation. However, some of these genes may not be
essential, and the functions may be complemented in trans
through the addition of growth factors or by plating the infected cells
on feeder cultures, which would provide essential factors in culture.
The deletion of the gp350 gene and the subsequent infection and
transformation of primary B cells in vitro suggests that this is
possible, although the efficiency is expected to be extremely low.
Further experiments are needed to determine if the infection and
transformation properties of this SNU-265 virus would provide some
clues as to the essential nature of these deleted genes. We are
currently investigating this line of experimentation to evaluate this
possibility and its potential for the development of another
cell line for recombination assays within the EBNA3 family of genes.
| |
ACKNOWLEDGMENTS |
We thank Elliott Kieff for the BJAB and B95-8 cell lines and
Martin Rowe for the A10 monoclonal antibody to EBNA3C. Probes used in
Southern blot analysis were obtained from the overlapping cosmids of
the EBV genome and were also kindly provided by Elliott Kieff.
Additionally, we thank Jae-Gahb Park for the SNU LCLs. We also thank
other members of the Robertson laboratory for assistance and support in
ensuring the completion of experiments. We particularly thank the
Department of Biological Sciences, Myongji University, for general and
sabbatical support for Wonkeum Lee.
This work was supported by National Cancer Institute grant CA072150-01
and National Institute of Dental and Craniofacial Research grant
DE14136-01 (to E.S.R) from the National Institutes of Health and by a
grant from the Lymphoma and Leukemia Society of America. E.S.R is a
Scholar of the Leukemia and Lymphoma Society of America.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, Comprehensive Cancer and Geriatrics
Center, University of Michigan Medical School, 3217 CCGC Bldg., Ann
Arbor, MI 48109-0934. Phone: (734) 647-7296. Fax: (734) 764-3562. E-mail: esrobert{at}umich.edu.
| |
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Journal of Virology, September 2001, p. 8556-8568, Vol. 75, No. 18
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.18.8556-8568.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
