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Previous Article | Next Article 
Journal of Virology, December 1999, p. 9908-9916, Vol. 73, No. 12
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Residues between the Two Transformation Effector Sites of
Epstein-Barr Virus Latent Membrane Protein 1 Are Not Critical for
B-Lymphocyte Growth Transformation
Kenneth M.
Izumi,
Ellen Cahir
McFarland,
Elisabeth A.
Riley,
Danielle
Rizzo,
Yuzhi
Chen, and
Elliott
Kieff*
Department of Medicine, Brigham and Women's
Hospital, Channing Laboratories, and Department of Microbiology and
Molecular Genetics, Harvard Medical School, Boston, Massachusetts
02115-5804
Received 24 June 1999/Accepted 13 September 1999
 |
ABSTRACT |
Epstein-Barr virus (EBV) latent membrane protein 1 (LMP1) is
essential for EBV-mediated transformation of primary B lymphocytes. LMP1 spontaneously aggregates in the plasma membrane and enables two
transformation effector sites (TES1 and TES2) within the 200-amino-acid cytoplasmic carboxyl terminus to constitutively engage the tumor necrosis factor receptor (TNFR)-associated factors TRAF1, TRAF2, TRAF3,
and TRAF5 and the TNFR-associated death domain proteins TRADD and RIP,
thereby activating NF-
B and c-Jun N-terminal kinase (JNK). To
investigate the importance of the 60% of the LMP1 carboxyl terminus
that lies between the TES1-TRAF and TES2-TRADD and -RIP binding sites,
an EBV recombinant was made that contains a specific deletion of LMP1
codons 232 to 351. Surprisingly, the deletion mutant was similar
to wild-type (wt) LMP1 EBV recombinants in its efficiency in
transforming primary B lymphocytes into lymphoblastoid cell lines
(LCLs). Mutant and wt EBV-transformed LCLs were similarly efficient in
long-term outgrowth and in regrowth after endpoint dilution. Mutant and
wt LMP1 proteins were also similar in their constitutive association
with TRAF1, TRAF2, TRAF3, TRADD, and RIP. Mutant and wt EBV-transformed
LCLs were similar in steady-state levels of Bcl2, JNK, and activated
JNK proteins. The wt phenotype of recombinants with LMP1 codons 232 to
351 deleted further demarcates TES1 and TES2, underscores their central
importance in B-lymphocyte growth transformation, and provides a new
perspective on LMP1 sequence variation between TES1 and TES2.
| |
INTRODUCTION |
Epstein-Barr virus (EBV) infection
of resting primary human B lymphocytes usually does not result in lytic
virus infection. Instead, EBV DNA episomes persist in the cell nucleus
and express six nuclear proteins (EBNAs) and three integral
plasma membrane proteins (latent membrane proteins
[LMPs]) (reviewed in reference 31). These
proteins mediate the persistence of EBV DNA and the efficient
transformation of the infected cells into indefinitely proliferating
lymphoblastoid cell lines (LCLs) (reviewed in reference 30). Recombinant EBV-based genetic analyses
implicate five EBNAs and LMP1 as the critical proteins for lymphocyte
proliferation (5, 14, 26, 35, 39, 58, 71). LMP1 induces many of the phenotypic changes characteristic of EBV-transformed LCLs, and
LMP1 has transforming effects on immortalized rodent fibroblasts (1, 52, 74-76). Furthermore, LMP1 is expressed in
vivo in EBV-associated lymphoproliferative disease in
immunocompromised patients, in nasopharyngeal carcinoma, and in
Hodgkin's disease (57).
LMP1 is a constitutively activated receptor that engages cytoplasmic
signal-transducing proteins characteristic of tumor necrosis factor
receptors (TNFRs). LMP1 is composed of a 24-amino-acid (aa) cytoplasmic
amino terminus, six hydrophobic membrane-spanning segments separated by
short turns that function collectively, and a 200-aa cytoplasmic
carboxyl terminus (see Fig. 1) (30). The six hydrophobic
membrane-spanning segments enable LMP1 molecules to aggregate in the
cell plasma membrane independently of an exogenous ligand (23, 26,
37, 75, 76), while the cytoplasmic carboxyl terminus has two
sites that constitutively associate with TNFR signal-transducing
proteins (24, 53). Site 1 is within the membrane-proximal 45 aa of the cytoplasmic carboxyl terminus and engages TRAF1, TRAF3,
TRAF5, and TRAF2 (2, 6, 8, 53, 61). Site 2 is within the
distal 35 aa of the carboxyl terminus and engages the TNFR-associated
death domain proteins TRADD and RIP (10, 21, 24). In
contrast to TNFRs that recruit TRAFs or TRADD and RIP after binding to
ligand and receptor aggregation, LMP1 continuously associates with
these proteins through these two sites (4, 6, 8, 21, 24, 53, 66,
73). Signaling through site 1 induces NF-B activation and
upregulates expression of TRAF1 and EBI3 in lymphocytes and of the
epidermal growth factor receptor in epithelial cells, whereas signaling
through site 2 induces NF-B and c-Jun N-terminal kinase activation,
but cannot up-regulate TRAF1, EBI3, or epidermal growth factor receptor
expression (7, 8, 10, 16, 20, 32, 44, 46, 48).
Previously reported recombinant EBV reverse genetic analyses using
primary B-lymphocyte transformation assays indicated that the LMP1
transmembrane segments and sites 1 and 2 in the carboxyl terminus are
key components for primary B-lymphocyte growth transformation (22,
24, 26, 28). Deletions of specific amino acid sequences from the
cytoplasmic amino terminus have little or no effect on transformation
by the recombinant EBV as long as arginines and prolines are expressed
to tether the first membrane-spanning segment to the cytoplasm
(22). Consistent with a stringent requirement for six
properly anchored transmembrane segments to achieve aggregation of LMP1
molecules in the plasma membrane, LMP1 lacking the amino terminus and
first transmembrane segments accumulates in the plasma membrane, but
does not aggregate or support primary B-lymphocyte growth
transformation (26). Site 1 is necessary and sufficient for
the initiation of lymphocyte transformation (28). The EBV recombinant MS231, which expresses an LMP1 that is carboxy-terminally truncated after site 1, can growth transform B lymphocytes when the
transformed cells are cocultivated with fibroblasts, whereas the EBV
recombinant MS187, which expresses an LMP1 that is carboxy-terminally truncated before site 1, cannot growth transform B lymphocytes. Furthermore, EBV recombinants with deletion of DNA that encodes the
TRAF binding site cannot transform B lymphocytes (22). The importance of site 2 is based on the phenotype of a recombinant with a
double point mutation of LMP1 Y384Y385 to
isoleucine. This mutation abrogates TRADD binding and cripples
transformation, as measured by LCL outgrowth without fibroblast
cocultivation (24). Because of genetic and biochemical
evidence that sites 1 and 2 are critical for effecting lymphocyte
transformation, we use the designation transformation effector sites 1 and 2 (TES1 and -2, respectively).
The experiments reported here are designed to investigate the
importance of the 60% of the LMP1 cytoplasmic carboxyl terminus between TES1 and TES2 (aa 232 to 351 [Fig. 1]). These residues are
potentially important in signaling and in positioning TES1 or TES2 for
interaction with cell proteins. Included in this part of the carboxy
terminus are four direct, imperfect repeats of a conserved PQDPDNTDDNG
sequence (aa 253 to 301); a PPQLT sequence (aa 320 to 324) that
resembles a PxQxT/S TRAF binding core, but does not function as one; a
protease cleavage site that has a role in LMP1 catabolism; 19 potential
serine or threonine phosphorylation sites, including the major
phosphorylated amino acids S313 and T324; and
sequences that vary in human isolates and have been reported to affect
the ability of LMP1 to transform immortalized rodent fibroblasts
(6, 8, 12, 19, 36, 38, 40, 50, 51). To evaluate the
importance of aa 232 to 351, an EBV recombinant with these codons
deleted has been generated by second site homologous recombination with
EBV P3HR-1, and the recombinant phenotype has been characterized in
primary B-lymphocyte growth transformation assays (70).
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MATERIALS AND METHODS |
Cells, virus, growth of infected cells, and assays of effects of
cell density on regrowth.
P3HR-1 (42), IB4
(43), BJAB (41), LCLs, and 293 cells were grown
as described elsewhere (6, 23). To test the effects of cell
density on regrowth, LCLs were serially diluted and seeded into 96-well
plates at 30,000 to 1,250 cells/well. Fresh medium was added to
cultures after 1 week, and LCL regrowth was monitored for 3 weeks.
LMP1 DNA clones.
EcoRI A and pSVNaeZ DNAs are
described elsewhere (67, 70, 71). Plasmid DNA Flag-LMP1 was
made by replacing codons 2 to 4 of synthetic wild-type (S-wt) DNA
(23) with codons for the Flag antibody epitope (Sigma)
between the unique ClaI and XbaI sites, placing a
NotI site at a HindIII site at nucleotide (nt) 166480 and a PacI site at a BglII site (nt
169037). Plasmid DNA Flag-LMP1
232-351 joins the NaeI
site (nt 168627) with a Klenow-filled NcoI site (nt 168758).
Expression vectors pSG5 Flag-LMP1 and pSG5 Flag-LMP1232-351 are
2.4- and 2.0-kb MluI DNA fragments from plasmid Flag-LMP1 or
plasmid Flag-LMP1232-351 inserted into the Klenow-blunted
BamHI site of pSG5 (Stratagene).
NF-B activation.
A total of 2.5 × 105
293 cells were transformed with LMP1 expression vector, 3×-B-L
luciferase reporter (A gift from Bill Sugden, University of Wisconsin,
Madison) (48), and a pGK-
gal transfection control and
analyzed as described elsewhere (6).
Recombinant EBV construction, Western blotting, in situ
immunofluorescence, and coimmunoprecipitation analyses.
Recombinant EBV232-351 was made by second site homologous
recombination as described elsewhere (59, 72). EBV proteins were detected by Western blotting and by in situ immunofluorescence and
were coimmunoprecipitated as described elsewhere (23, 28, 59).
| |
RESULTS |
An EBV recombinant with LMP1 codons 232 to 351 deleted is competent
for primary B-lymphocyte growth transformation.
An EBV LMP genomic
clone with an in-frame deletion of codons 232 to 351 and with an
insertion of codons for the Flag epitope within the amino-terminal
cytoplasmic domain was constructed as described in Materials and
Methods. The predicted protein has the Flag epitope and a shorter
carboxyl-terminal cytoplasmic tail with TES1 juxtaposed with TES2 (Fig.
1). The deleted sequence comprises the
epitope recognized by the LMP1-specific monoclonal antibody S12.
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FIG. 1.
Diagram of LMP1. The Flag epitope was introduced at the
amino terminus (NH2). The positions of residues 187, 231, 352, and 386 are marked. LMP1 aggregates in the plasma membrane and
constitutively associates with TRAFs, TRADD, and RIP. TES1 is located
between residues 187 to 231 and aggregates TRAF1, -2, -3, and -5 to
mediate NF-B activation and initial B-lymphocyte growth
transformation. TES2 is located between residues 352 and 386;
aggregates RIP or TRADD, which associate with TRAFs to mediate
high-level NF-B and c-Jun N-terminal kinase (JNK) activation; and
enables permanent LCL outgrowth.
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Flag-LMP1232-351 DNA was recombined into the P3HR-1 EBV
genome by the second site homologous recombination method. In brief, P3HR-1 cells have an endogenous EBV that is competent for virus replication, but the virus is transformation defective due to a
deletion of DNA that codes for EBNA2 and EBNA LP. When 107
P3HR-1 latently infected cells are cotransfected with a cosmid DNA that
spans the P3HR-1 deletion, a mutated LMP1 DNA, and an expression vector
for the EBV immediate-early transactivator BZLF1, virus replication is
induced in the transfected cells and about 107 virions are
produced. Almost all are parental P3HR-1 EBV, but about 102
to 103 recombinants with the cosmid DNA are also produced,
and these recombinants are able to transform resting human B
lymphocytes into proliferating cells. Under optimal conditions, 10% of
those recombinants will have undergone homologous recombination
with and incorporated the mutated LMP1 DNA. When this mixture of
viruses is used to infect about 108 B lymphocytes and the
infected cells are plated into 2,000 microwells, as many as one-half of
the wells are positive for LCLs.
About one-third of the virus from a P3HR-1 cell cotransfection was used
to infect resting primary B lymphocytes from a healthy human donor, and
630 recombinants were recovered, as evidenced by the number of
resulting LCLs. A sample of 245 LCLs were further analyzed by PCR for
their LMP1 genes. Five of the 245 (2%) LCLs were found to have the
Flag-LMP1232-351 DNA, whereas the remaining 240 encoded only wt
LMP1 DNA from P3HR-1. All five Flag-LMP1232-351 DNA-containing LCLs were coinfected with P3HR-1 EBV. The smaller than expected percentage of Flag-LMP1232-351 recombinants might be
due to recombination constraints imposed by the interruptions of DNA
homology at the Flag codon insertion and codon 232-to-351 deletion
sites, to a third critical transformation effector site within the
deletion, or to a role for the deleted amino acids in protein folding
or stability.
To establish the transformation phenotype of the Flag-LMP1232-351
recombinants, one Flag-LMP1232-351 recombinant LCL was transfected
with the BZLF1 expression vector to reactivate virus replication, and
fresh primary B lymphocytes were infected with the resulting virus
progeny. Hundreds of second-generation LCLs resulted, and 140 were
examined by PCR for the Flag epitope that is characteristic of the
Flag-LMP1232-351 DNA. Two-thirds of the 140 were infected with a
Flag-LMP1232-351 EBV recombinant. Twenty-four of these LCLs were
selected because the PCR analysis indicated the presence of the Flag
codon insertion, but revealed no signal that indicated wt P3HR-1 LMP1
DNA without the Flag codon insertion (data not shown). By another PCR
analysis that scores specifically for wt LMP1 DNA, 2 of the 24 LCLs
were found to have less than 1 wt LMP1 DNA molecule in 1,000 cells. Of
the others, 3 LCLs had no more than 1 wt LMP1 DNA in 100 cells, 9 had
no more than 1 wt LMP1 DNA in 10 cells, and 10 had about 1 wt LMP1 DNA per cell. The two LCLs having no more than 1 wt LMP1 DNA in 1,000 cells
were cloned by limiting dilution, and two cell lines (24-68 and
33-15) were established in which no wt LMP1 DNA could be detected
at a level of sensitivity of 1 LMP1 DNA in 104 cells.
The LMP1 genes in the 24-68 and 33-15 LCLs were further
analyzed by PCR (Fig. 2). Primers that
are specific for wt LMP1 amino-terminal codons amplified DNA of the
expected size from IB4 cells, which have four integrated EBV genomes
per cell. This procedure could detect 1 IB4 cell diluted with
104 EBV-negative BJAB cells (Fig. 2A, lane 4). In lanes 9 and 10, wt LMP1 DNA was not detected in 104 24-68 or
33-15 LCLs. This indicates that the 24-68 and 33-15 LCLs
have no wt LMP1 DNA, with a sensitivity of 4 LMP1 genes in 104 cells. In panel B, another set of primers that are
identical to codons 232 to 240 and complementary to codons 315 to 323 amplified wt LMP1 DNA of the expected size when at least 1 IB4 cell was diluted with DNA from 104 EBV-negative BJAB cells (lane 4),
whereas no DNA was detected in lanes 9 and 10 from 104
24-68 and 33-15 LCLs. DNA of the expected wt size was amplified from 104 Flag-wt1 (F-wt1) and F-wt2 LCLs which are infected
with Flag-wt LMP1 recombinants (lanes 11 and 12). In panel C, primers
were used that amplify LMP1 amino-terminal codons from P3HR-1 cells, which have wt LMP1 DNA (lane 2) or plasmid Flag-LMP1232-351 DNA (lane 1). The PCR product from plasmid Flag-LMP1232-351 DNA is larger due to the Flag codon insertion. Lysates from 104
24-68 and 33-15 LCLs (lanes 3 and 4) yielded a PCR product similar in size to DNA amplified from the plasmid Flag-LMP1232-351 DNA that was used in their construction. F-wt1 and F-wt2 LCLs (lanes 5 and 6) have Flag-LMP1 DNA which amplified a DNA of similar size because
of the Flag codon insertion. In panel D, primers that flank the coding
sequence of the carboxyl-terminal tail amplified a smaller product from
plasmid Flag-LMP1232-351 DNA (lane 1) than P3HR-1 cells, which have
wt LMP1 DNA (lane 2). The DNA from 104 24-68 and
33-15 LCLs (lanes 3 and 4) produced PCR products that were similar
in size to the DNA amplified from plasmid Flag-LMP1232-351 DNA used
in their construction. DNA from F-wt1 and F-wt2 LCLs which are infected
with Flag-LMP1 recombinants (lanes 5 and 6) amplified DNA similar in
size to that amplified from P3HR-1 cells which have wt LMP1 DNA (lane
2). Thus, 24-68 and 33-15 LCLs have no apparent wt LMP1 DNA
with a sensitivity of 4 EBV DNA copies in 10,000 cells, and both the
codon 232-to-351 deletion and the Flag codon insertion are evident.
These results indicate that LMP1 aa 232 to 351 are not essential for
EBV-mediated transformation of primary B lymphocytes into indefinitely
proliferating lymphoblastoid cell lines.
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FIG. 2.
PCR analyses of mutated LMP1 recombinant EBV-infected
LCLs for LMP1 DNA. (A) PCR analysis for wt amino-terminal LMP1 DNA with
the primers 5'-GAGGATGGAACACGACCTTGAGA-3' and
5'-CTCCAGTCCAGTCACTCATAACG-3'. Lanes 8 to 2 are
104 IB4 cells (4 EBV DNA per cell) serially 10-fold diluted
with 104 EBV-negative BJAB cells. After PCR amplification,
DNAs were size separated in 3% agarose gels containing ethidium
bromide. The endpoint dilution (lane 4) is the 10 4
dilution for a sensitivity of 4 copies of LMP1 DNA per 104
cells. No wt LMP1 DNA was detected in 104 24-68 LCLs
(lane 9) or 33-15 LCLs (lane 10) or in water (lane 1). Molecular
markers (in base pairs) are indicated to the left of each panel. (B)
PCR analysis for wild-type carboxyl-terminal LMP1 DNA as in panel A,
except that the primers 5'-GACGGACCCCCACTCTGCTCTC-3' and
5'-ATTGTGGAGGGCCTCCATCATTTC-3' were used. (C) PCR analysis
for Flag-LMP1 and wt LMP1 amino-terminal DNA as in panel A, except that
the primers 5'-CACGCGTTACTCTGACGTAGCCG-3' and
5'-CTCCAGTCCAGTCACTCATAACG-3' were used. (D) PCR analysis
for Flag-LMP1232-351 deletion mutant and wt LMP1 carboxyl-terminal
DNA as in panel A, except that the primers
5'-CTCTATTGGTTGATCTCCTTTGG-3' and
5'-GCCTATGACATGGTAATGCCTAG-3' were used.
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Flag-LMP1232-351 LMP1 recombinants transform primary B
lymphocytes de novo with wt efficiency.
The ability of the
Flag-LMP1232-351 EBV recombinants to transform primary B
lymphocytes was compared with that of Flag-LMP1 recombinants, which are
isogenic except for their LMP1 genes. 24-68, 33-15, F-wt1, and
F-wt2 LCLs were induced to lytic infection, and filtered viruses
prepared from the LCLs were serially diluted and then used to infect
primary B lymphocytes. In Table 1, the filtered virus DNA titer as determined by endpoint dilution PCR and the
number of LCLs growing in microwells 6 weeks after infection at each
virus dilution are compared. All LCLs replicated virus, and all viruses
were transformation competent. F-wt1 LCL produced the smallest amount
of virus, and EBV from this LCL produced the fewest LCLs at every
dilution. 24-68 LCL produced more virus than F-wt1 LCL, and EBV
from 24-68 LCL produced more LCLs at every dilution. The virus DNA
titer was less than that of F-wt2 or 33-15 LCLs, but EBV from the
24-68 LCL was similar to EBV from the F-wt2 LCL in the number of
transformed cell lines. F-wt2 and 33-15 LCLs produced similar
amounts of virus, but EBV from 33-15 LCLs produced slightly more
transformed cell lines. Clearly, Flag-LMP1232-351 recombinants are
quite similar to Flag-LMP1 recombinants in replication and in primary
B-lymphocyte transformation.
Flag-LMP1232-351 recombinant EBV transformants
proliferate into long-term LCLs with wild-type efficiency.
Ten LCLs transformed by each of the four virus stocks from F-wt1,
F-wt2, 24-68, or 33-15 LCLs were continuously subcultivated in
vitro to compare the efficiency of long-term LCL outgrowth of cells
with that of the second-passage Flag-LMP1232-351 or F-LMP1 EBV
recombinants. All of these LCLs continued to expand for the ensuing 6 months in culture. Thus, these cell lines did not differ in their
growth rate or ability to expand into long-term LCLs.
Flag-LMP1232-351 LMP1 and Flag-LMP1 recombinant-transformed
LCLs are similar in the endpoint dilution from which they can
regrow.
LCLs are dependent on cross-feeding for rapid growth. Even
after 6 months of continuous subcultivation, LCLs typically require seeding between 104 to 105 cells per ml of
complete culture medium in order regrow to 106 cells per ml
by 21 days. Subtle growth defects are frequently most evident when
cells are challenged by plating at low cell density (15, 28,
77). The inherent sensitivity to dilution of cells transformed by
Flag-LMP1232-351 or F-LMP1 EBV recombinants was therefore
determined by seeding serial dilutions of cells into 96-well plates at
cell concentrations from 30,000 to 1,250 cells per 0.1 ml of medium.
LCL outgrowth was monitored over the course of 3 weeks, and the results
are presented in Table 2. The progenitor
F-wt1, F-wt2, 24-68, or 33-15 LCLs efficiently regrew when
plated at 6,000 to 11,000 cells per 0.1 ml, but not when plated at a
lower cell density. Two cell lines transformed by recombinant EBV
passaged from each progenitor were tested for regrowth after endpoint
dilution. The endpoint dilutions for regrowth of second-passage EBV
recombinant-transformed LCLs were 2,500 and 
5,000 for F-wt1, 1,250
and 5,000 for Fwt-2, 1,250 and 1,250 for 24-68, and 1,250 and
5,000 for 33-15. Thus, Flag-LMP1232-351 recombinant-transformed LCLs are similar to Flag-LMP1
recombinant-transformed LCLs in their sensitivity to low-density
plating.
EBNA and LMP1 expression levels and LMP1 aggregation are similar in
Flag-LMP1232-351 and Flag-LMP1 recombinant EBV-transformed
LCLs.
LMP1 characteristically aggregates in a single area in LCL
plasma membranes. LMP1 was localized by indirect immunofluorescence on
fixed and permeabilized wt, Flag-LMP1, and Flag-LMP1232-351 recombinant-transformed LCLs (Fig. 3).
Flag-LMP1 in the F-wt2 LCL was detected in plasma membrane aggregates
by using M5 monoclonal antibody to Flag (Fig. 3B) or S12 monoclonal
antibody that recognizes an epitope within LMP1 aa 232 to 351 (Fig.
3E). An LCL transformed by an EBV recombinant with a wild-type LMP1
that does not have a Flag epitope tag stained similarly with S12 (Fig.
3F) but not M5 antibody (Fig. 3C). Flag-LMP1232-351 in the
33-15 LCL was immunoreactive in similar membrane aggregates with M5
antibody (Fig. 3A), but was not detected with S12 antibody (Fig. 3D).
The same results were obtained with the 24-68 LCL (data not shown). Thus, deletion of aa 232 to 351 does not alter LMP1 plasma membrane localization or aggregation.
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FIG. 3.
Indirect immunofluorescent staining of methanol and
acetone-fixed lymphoblastoid cell lines with M2 monoclonal antibody to
Flag or S12 monoclonal antibody to the LMP1 carboxyl terminus. LMP1
spontaneously aggregates in the plasma membrane.
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Flag-LMP1 levels were measured by M2 Flag antibody precipitation of
Flag-LMP1, size separation in denaturing polyacrylamide gels, and
Western immunoblot detection with M5 Flag antibody. In Fig.
4A, a protein of about 60 kDa is present
in F-wt1 (lane 1) and F-wt2 (lane 2) LCLs. A prominent, nonspecific
band just below Flag-LMP1 is detected in all lanes of the blot. Two
proteins of about 40 kDa are present in the 24-68 (lane 4) and
33-15 (lane 5) LCLs, which express Flag-LMP1232-351. The sum of
the two protein band intensities of Flag-LMP1232-351 is similar to that of Flag-LMP1, consistent with the similar level of
immunofluorescent staining in situ (Fig. 3). M5 antibody does not
detect LMP1 in immunoprecipitates from an LCL that expresses wild-type
LMP1 without the Flag epitope tag (Fig. 4, lane 3). In Fig. 4B, F-wt1,
F-wt2, and wt LMP1 LCLs have similar quantities of LMP1 in
unfractionated cell lysates, as detected by immunoblotting with S12
monoclonal antibody. S12 reactive, full-length LMP1 is absent from the
24-68 and 33-15 LCLs (lanes 4 and 5). These results confirm
that the 24-68 and 33-15 LCLs do not express the 60-kDa LMP1
but do express the 40-kDa Flag-LMP1232-351. Furthermore,
deletion of residues 232 to 351 abolishes the S12 monoclonal antibody
epitope, which is likely within the imperfect repeat sequences.
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FIG. 4.
Protein expression in recombinant EBV-infected LCLs. (A)
Western immunoblot analysis for Flag-LMP1. About 108 cells
were Dounce homogenized in buffer containing 0.5% Brij 58, 100 mM
NaCl, and 50 mM Tris (pH 7.2) and cleared by centrifugation. Flag-LMP1
was immunoprecipitated with M2 affinity gel (Sigma) for 6 h.
Affinity gel was washed once, and precipitated proteins were detached
with buffer containing SDS and 2-mercaptoethanol. About 10% of the
immunoprecipitates were size separated in denaturing polyacrylamide
gels, blotted to nitrocellulose filters, probed with M5
monoclonal antibody to Flag (Sigma) and peroxidase-conjugated secondary
antibody to mouse immunoglobulin G (Amersham), and
visualized by enhanced chemiluminescence (NEN Life Science). The
position of Flag-LMP1 (F-L) is marked on the left, and the position of
Flag-LMP1232-351 (F-L) is marked on the right. (B) Western
immunoblot analysis for LMP1 carboxyl-terminal amino acids. About
5 × 104 cells were lysed in buffer containing SDS and
2-mercaptoethanol and resolved in denaturing polyacrylamide gels. After
Western transfer to nitrocellulose filters, LMP1 was detected as in
panel A, except S12 monoclonal antibody was used. The position of
Flag-LMP1 (F-L) or LMP1 (L) is marked on the left. (C) Western
immunoblot analysis for EBV nuclear antigens (EBNA) leader
protein (LP), EBNA1, EBNA2, and EBNA3C. The position of each
protein is marked on the left. Analysis was done as in panel B, except
that serum from a normal human donor and peroxidase-conjugated
secondary antibody to human immunoglobulin G were used. In all panels,
molecular mass markers (in kilodaltons) are marked on the right.
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Expression of EBV nuclear proteins EBNA LP, -1, -2, and -3C was
examined by Western immunoblotting with immune human serum. In
unfractionated cell lysates, levels of EBNA1 and EBNA2 were prominent
and equivalent in F-wt1, F-wt2, wt, 24-68, or 33-15 LCLs (Fig.
4C). EBNA LP staining was more diffuse, but the levels were
approximately the same in the five LCLs. Detection of EBNA3C required
extended exposure to film, but the relative levels were similar in the
five LCLs. Thus, Flag-LMP1232-351, Flag-LMP1, and wt LMP1 EBV
recombinant-transformed LCLs are not different in latent EBV gene expression.
Flag-LMP1232-351 is similar to Flag-LMP1 in inducing NF-B
activation.
Since NF-B activation by TES1 and TES2 is
genetically linked to B-lymphocyte transformation and likely to be
pathophysiologically relevant, we tested the ability of
Flag-LMP1232-351 to activate an NF-B-responsive luciferase
reporter in transiently transfected 293 human embryonic kidney cells.
Transfection of 32, 100, 320, or 1,000 ng of Flag-LMP1- or
Flag-LMP1232-351-expressing vectors activated NF-B progressively
with more DNA (Fig. 5A). Higher levels of
NF-B activation correlated with higher LMP1 expression (Fig. 5B).
Flag-LMP1232-351 was consistently as active or somewhat more active
than Flag-LMP1.
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FIG. 5.
F-LMP1- and F-LMP1232-351-expressing vectors
activate NF-B. (A) HEK293 cells (2.5 × 105) were
transfected (Qiagen Superfect) with the indicated amounts of F-LMP1- or
F-LMP1232-351-expressing vector or pSG5 vector control and with 350 ng of 3X-B-L, a luciferase reporter with three NF-B sites from
human major histocompatibility class I and Fos minimal promoter and
with 350 ng of pGK--gal DNA, a -galactosidase-expressing vector
used to monitor transfection efficiency. After 20 h at 37°C,
cells were lysed in reference lysis buffer (Promega) and analyzed for
luciferase activity (Promega) and -galactosidase expression (Tropix)
according to the manufacturer's directions. (B) Western immunoblot
analysis for F-LMP1 or F-LMP1232-351. Equivalent amounts of protein
from lysates prepared as described above were size separated and
analyzed as described in the legend to Fig. 4A. The position of F-LMP1
or F-LMP1232-351 is marked on the left.
|
|
Flag-LMP1232-351 and Flag-LMP1 constitutively associate with
signaling proteins in LCLs.
Flag-LMP1 association with signaling
proteins was examined by immunoprecipitation with Flag antibody M2 and
Western immunoblot analysis. The death domain-containing proteins
TRADD and RIP coprecipitated with Flag-LMP1 and Flag-LMP1232-351
with about the same efficiency, whereas neither protein
coprecipitated with Flag antibody with extracts from an LCL transformed
by an EBV recombinant that expresses a wt LMP1 that lacks Flag (Fig.
6). TRAF1, TRAF2, and TRAF3 also coprecipitated at about the same level with Flag antibody with Flag-LMP1- or Flag-LMP1232-351-transformed LCL extracts, whereas TRAFs did not coprecipitate from extracts of wt LMP1-transformed LCLs.
The efficiencies of immunoprecipitation of Flag-LMP1 and Flag-LMP1232-351 were similar, whereas Flag antibody precipitated only a trace amount of wt LMP1. These biochemical results are consistent with the aa 232-to-351 deletion being similar to wild-type EBV in effecting EBV-mediated growth transformation.
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|
FIG. 6.
Coimmunoprecipitation of TRAF1, TRAF2, TRAF3, TRADD, or
RIP with F-LMP1 or F-LMP1232-351. Proteins from LCLs (2.0 × 108 cells) infected with F-LMP1, F-LMP1232-351, or a wt
LMP1 EBV recombinant were solubilized by Dounce disruption in 0.5%
Brij 58, 100 mM NaCl, and 50 mM Tris (pH 7.2) and immunoprecipitated
with M2 affinity gel (Sigma) to Flag. Precipitated proteins were
Western immunoblot analyzed with antibodies to TRAF1, TRAF2, TRAF3, and
TRADD from Santa Cruz Biotechnology, antibody to RIP from Pharmingen,
or M5 antibody to Flag from Sigma. Input lanes represent unfractionated
cell proteins, unbound lanes represent proteins not precipitated with
M2 affinity gel, and Imm Ppt lanes represent immunoprecipitated
proteins.
|
|
LCLs transformed by Flag-LMP1232-351, Flag-LMP1, and wt LMP1
EBV recombinants are similar for levels of JNK1 and JNK2,
phosphorylated JNK1 and JNK2, and Bcl2.
LMP1 activates c-Jun
N-terminal kinase (JNK) and upregulates Bcl2 levels (10, 11, 16,
32, 60, 68). Steady-state levels of JNK1 and JNK2, phosphorylated
JNK1 and JNK2, and Bcl2 were assayed by Western immunoblotting. Western
immunoblot analysis with an antibody that recognizes JNK1 and JNK2
detects similar levels of JNK1 and JNK2 in LCLs transformed by
Flag-LMP1232-351, Flag-LMP1, and wt LMP1 EBV recombinants (Fig.
7A). Western immunoblot analysis with an
antibody that recognizes the phosphorylated forms of both JNK1 and JNK2
detects phosphorylated JNK2 (P-JNK2) at similar levels in LCLs
transformed with EBV recombinants that express Flag-LMP1232-351,
Flag-LMP1, and wt LMP1. Although the antibody recognizes both P-JNK1
and P-JNK2, P-JNK1 is not detected in any of these LCLs (Fig. 7B).
These results indicate that P-JNK2 is the predominant activated JNK in
LCLs and that LCLs transformed by Flag-LMP1232-351 recombinants are
similar in JNK activation. Western immunoblot analysis with antibody to
Bcl2 reveals that the Bcl2 levels are similar in all of these LCLs
(Fig. 7C). These results demonstrate that residues 232 to 351 are not
involved with activating JNK2 or with regulating Bcl2, JNK1, or JNK2
levels.
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|
FIG. 7.
Western immunoblot analysis for c-Jun N-terminal kinase
1 and 2 (JNK1 and JNK2), phosphorylated JNK1 and JNK2 (P-JNK1 and
P-JNK2), and Bcl2. LCLs (1.5 × 106) transformed with
F-LMP1, F-LMP1232-351, or a wt LMP1 EBV recombinant were directly
lysed in buffer containing SDS and 2-mercaptoethanol. Cell proteins
were resolved in denaturing polyacrylamide gels, Western
blotted to nitrocellulose filters, and probed with antibodies. (A) JNK1
and JNK2 are detected at similar levels in all LCLs with an antibody
that recognizes JNK1 and JNK2 (New England Biolabs). (B) P-JNK2 but not
P-JNK1 is detected at similar levels in all LCLs with an antibody that
specifically recognizes P-JNK1 and P-JNK2 (New England Biolabs). (C)
Bcl2 protein is detected at similar levels in all LCLs with a
Bcl2-specific antibody (Santa Cruz Biotechnology).
|
|
| |
DISCUSSION |
These data indicate that LMP1 aa 232 to 351 are not critical for
primary B-lymphocyte growth transformation in vitro. The assays
employed to compare the phenotypic characteristics of
Flag-LMP1232-351 with Flag-LMP1 EBV recombinants have previously
revealed differences between mutant and wt EBV recombinants in a
reduced efficiency of initial lymphocyte growth transformation, in a
reduced efficiency of LCL outgrowth at various stages of expansion from
the initial transformants, or in an increased cell density dependence
(15, 23, 27, 28, 77). The absence of any phenotypic
difference between Flag-LMP1232-351 and Flag-LMP1 EBV recombinants
in these three assays and the absence of any biochemical difference
between Flag-LMP1232-351 and Flag-LMP1 in association with cell
signaling proteins, NF-B activation, JNK activation, or altered cell
gene expression indicates that aa 232 to 351 are not important for lymphocyte growth transformation in vitro. These results also underscore the principal positive effector roles of TES1 and TES2 in
primary B-lymphocyte growth transformation. This result is consistent
with previous recombinant genetic analyses of the role of the LMP1
carboxyl terminus in B-lymphocyte growth transformation. The previous
experiments showed that the LMP1 amino terminus, transmembrane
segments, and TES1 are sufficient for initial primary B-lymphocyte
growth transformation in the absence of the LMP1 carboxyl-terminal 155 aa (27, 28). Cocultivation with fibroblast feeder cells is
required for efficient long-term LCL outgrowth after transformation by
the MS231 EBV recombinant that expresses LMP1 aa 1 to 231. TES2 appears
to be critical for efficient long-term LCL outgrowth, since a double
point mutation at the carboxyl terminus of TES2 has a phenotype that is
similar to that of MS231 (24). Although there remains the
possibility that a point mutant in the TES1 core TRAF binding site can
transform when the infected cells are cocultivated with fibroblasts,
the data thus far are consistent with a model in which TES1 is the most
important effector site overall, and TES2 is the principal effector
site in the carboxyl-terminal 155 aa. Certainly, aa 232 to 351 are not
important for efficient primary B-lymphocyte growth transformation in vitro.
Either LMP1 residues 232 to 351 are unimportant for primary
B-lymphocyte growth transformation, or there are multiple domains within this region, some positive and some negative, such that removal
of the entire region has no net effect. Indeed, aa 232 to 351 include
four copies of an 11-residue repeat, a site for protease-specific
cleavage, sites proposed to interact with Janus kinase 3 (JAK3) and
mediate the activation of signal transduction and activation of
transcription (STAT) proteins, and sites for specific serine/threonine
phosphorylation that are highly conserved among EBV isolates (12,
13, 38, 40, 50, 51). The wt transforming ability of
Flag-LMP1232-351 EBV recombinants is compatible with the hypothesis
that LMP1's potential interaction with JAK3 does not mediate signaling
that is significant to the growth transformation of primary B
lymphocytes. We cannot exclude the possibility that this potential
interaction may have a subtle effect on some aspect of latent
infection. The absence from Flag-LMP1232-351 of the normal protease
cleavage site between asparagine 241 and leucine 242 might have been
expected to result in increased accumulation of the deletion mutant
LMP1, but Flag-LMP1232-351 was similar in abundance to wt LMP1. No
other functional consequences have been attributed to the protease
cleavage (52). Furthermore, a previous mutation of the
secondary phosphorylation site at T324 to a glutamic acid
resulted in an LMP1 that appeared to be unable to transform Rat-1
cells, as measured by a cell contact inhibition assay (51).
This finding raised the expectation that deletion of this site would
affect B-lymphocyte growth transformation.
The LMP1 aa 232-to-351 deletion includes 9 of the 10 residues (aa 343 to 352) that are deleted from EBV strains that are endemic to southern
Chinese ethnic groups that have elevated relative risk for
nasopharyngeal carcinoma (19). The same deletion has been
noted in some American and European EBV strains, including viral
genomes in some Hodgkin's lymphoma tumor cells and in some patients
with lymphoproliferative disease (9, 29, 33, 34, 47, 54-56, 65,
69). Experimental studies comparing the effects of the aa
343-to-352 deletion mutant LMP1 with wild-type LMP1 in BALB/c 3T3 cells
indicate that the deletion may be associated with increased
transforming effects (36). However, the specific association
of this deletion with malignancies has not been documented by formal
epidemiological criteria, and recent data indicate this deletion is
present in other ethnic groups (17, 18, 64). Furthermore,
lymphocytes natively transformed by EBV strains that have the aa
343-to-352 deletion mutant LMP1 are not more tumorigenic in nude or
SCID mice, and the deletion has not been associated with poorer
outcomes in EBV-associated human lymphoproliferative disease
(3, 17, 18, 62, 63). Moreover, LMP1 with aa 343 to 352 deleted did not differ from wild-type LMP1 in NF-B activation or in
induction of CD40 or CD54 surface expression on B-lymphoma cells
(25, 45). Thus, the overall significance of this deletion in
the pathogenesis of EBV-related malignancies is uncertain.
The absence of a phenotype in B-lymphocyte transformation assays with
deletion of aa 232 to 351 may not be fully predictive of the role of
these sequences in vivo. In immunocompetent humans, LMP1 is expressed
during lytic EBV infection in oropharyngeal epithelial cells, in type
III latency that accompanies primary infection in B lymphocytes, and in
type II latency in some circulating B lymphocytes. LMP1 is also
expressed in EBV-associated nasopharyngeal carcinoma, Hodgkin's
lymphoma, and in some leiomyosarcomas of the intestine (reviewed in
reference 57). In these various tissues or stages of
EBV infection, aa 232 to 351 may have a role in regulating the effects
of TES1 or TES2 or may have other effects that are independent of TES1
or TES2. Amino acids 232 to 351 are highly conserved in all EBV
isolates and are therefore likely to have an important role in some
aspect of normal EBV infection in vivo. Comparison of the biological
properties of mutant versus wt transformed lymphocytes in SCID mouse
tumorigenesis models may reveal some difference. However, the
difference may be subtle and require study in a primate
lymphocryptovirus infection model (49).
The finding that residues 232 to 351 are not important for lymphocyte
growth transformation is an important step in defining the
amino-terminal boundary of TES2. Previously, TES2 was formally defined
by the double point mutation of Y384Y385 to
I384 (24). Clearly, aa 352 to 386 are a fully
competent TES2 for B-lymphocyte growth transformation in vitro. Since
the terminal 11 residues are sufficient to engage TRADD and
synergistically activate NF-B, the amino-terminal boundary of TES2
is likely to be closer to the carboxyl terminus than aa 352. However,
RIP also interacts with TES2, and the interaction appears to require
more than the terminal 11 residues (21). More precise
definition of the boundaries of TES2 and TES1 is important in
evaluating whether these sites have additional effector functions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Brigham and
Women's Hospital, 827 MCP Building, 181 Longwood Ave., Boston, MA
02115-5804. Phone: (617) 525-4252. Fax: (617) 525-4251. E-mail:
ekieff{at}rics.bwh.harvard.edu.
Present address: Integrated DNA Technologies, Inc., Brookline,
MA 02446.
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Abstract
Introduction
