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Journal of Virology, November 2001, p. 10941-10949, Vol. 75, No. 22
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.22.10941-10949.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
C-Terminal Domain of the Epstein-Barr Virus LMP2A Membrane
Protein Contains a Clustering Signal
Liudmila
Matskova,1
Ingemar
Ernberg,1
Tony
Pawson,2 and
Gösta
Winberg1,3,*
Karolinska Institutet, Microbiology and Tumor
Biology Center (MTC), SE-171 77 Stockholm,1
Swedish Institute for Infectious Disease Control, Department of
Virology, SE-171 82 Solna,3 Sweden, and
Samuel Lunefeld Research Institute, Mount Sinai Hospital,
Toronto M5G 1X5, Canada2
Received 14 June 2001/Accepted 17 August 2001
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ABSTRACT |
The latency-regulated transmembrane protein LMP2A
interferes with signaling from the B-cell antigen
receptor by recruiting the tyrosine kinases Lyn and Syk and by
targeting them for degradation by binding the cellular E3
ubiquitin ligase AIP4. It has been hypothesized that this constitutive
activity of LMP2A requires clustering in the membrane, but
molecular evidence for this has been lacking. In the present study we
show that LMP2A coclusters with chimeric rat CD2 transmembrane
molecules carrying the 27-amino-acid (aa) intracellular C
terminus of LMP2A and that this C-terminal domain fused to the
glutathione-S-transferase protein
associates with LMP2A in cell lysates. This molecular
association requires neither the cysteine-rich region
between aa 471 and 480 nor the terminal three aa 495 to 497. We
also show that the juxtamembrane cysteine repeats in the LMP2A C
terminus are the major targets for palmitoylation but that this
acylation is not required for targeting of LMP2A to
detergent-insoluble glycolipid-enriched membrane microdomains.
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INTRODUCTION |
Human herpesvirus 4 (Epstein-Barr
virus [EBV]) is a ubiquitous gammaherpesvirus carried by over 90% of
the human population. The virus remains tightly latent (latency I) in
small memory-type B cells that express EBNA-1 and the
latency-regulated transmembrane protein LMP2A (3, 10, 35).
The latter is believed to safeguard viral latency by abolishing
signaling from the B-cell antigen receptor (BCR) (27).
Successful activation of the B cell following stimulation of the BCR
would lead to concomitant activation of additional viral genes,
rendering the EBV-carrying B cell susceptible to immune attack. Thus,
LMP2A must have a key role in modulating the phenotype of the
EBV-carrying B cell to the advantage of the virus. But LMP2A is also
expressed in a majority of EBV-carrying anaplastic nasopharyngeal
carcinomas (10) and may contribute to the transformed
phenotype of these tumors.
The LMP2A transcription unit spans the termini of the viral genome
(23) and consequently can be transcribed from the
intracellular viral episome only after circularization of the linear
virion DNA. A coterminating transcript, LMP2B, lacks the first exon of LMP2A and is transcribed from a bidirectional promoter, shared with the other major latency-regulated membrane protein, LMP1 (22). The existence of LMP2B as a protein has so far not
been shown. The physically separate promoters of LMP2A and LMP2B
are subject to different transcriptional controls. While the promoters of LMP2A, LMP2B, and LMP1 depend on the viral nuclear protein EBNA2 for transactivation in B cells, the LMP2A promoter was shown to
respond to a murine homologue of the Drosophila
melanogaster Notch gene, mNotch
IC, which is expressed in hematopoietic cells (39).
The expression of LMP2A may thus be independent of other viral factors
in latency forms where EBNA2 is not expressed.
The mechanisms by which LMP2A modulates cellular signaling have been
the subject of extensive study. The unique first (N-terminal) exon in
LMP2A was shown to contain a functional immunotyrosine activation motif
similar to those found in the CD79
and CD79
auxiliary chains of
the BCR (4), and recent studies show that LMP2A associates
with lipid rafts (12, 19) and indicate that LMP2A
interferes with raft association of the BCR (12). The phosphorylated tyrosines 74 and 85 in the immunotyrosine activation motif of the LMP2A N-terminal exon are required for the binding of the
Syk tyrosine kinase (7, 14, 15), and tyrosine 112 acts
as a docking site for the Src family tyrosine kinase Lyn (16). Studies of LMP2A N-terminal deletion mutants
indicate, in addition, that the C-terminal Src kinase, Csk, may be
responsible for phosphorylation of Y74 in epithelial cells
(36). The extracellular regulated kinase (Erk) may further
affect phosphorylation of serine residues S15 and S102 in the LMP2A
N-terminal domain (30). Two proline-rich (PPPPY) motifs in
the N-terminal exon bind WW domains in the cellular E3 ubiquitin ligase
AIP4 (34, 44) and other related HECT domain proteins
(20, 43).
Unlike the LMP1 membrane protein, which mimics the signaling of an
activated CD40/tumor necrosis factor receptor (13), LMP2 proteins are not essential in the growth transformation
(immortalization) of B cells by EBV in vitro. However, when introduced
as a transgene in mice, LMP2A has been observed to provide a survival
signal, allowing immature B cells lacking a functional BCR to populate lymphoid organs and enter the peripheral circulation (8).
This may be due to antiapoptotic signals delivered by constitutive activation of the serine-threonine kinase Akt, which has been observed
in both EBV-transformed B cells (40) and epithelial cells
(37).
Early observations of membrane distribution of LMP1 and LMP2A using
immunofluorescence indicated that LMP1 and LMP2A were colocalized in
large patches on the membranes of B cells (24). The
subsequent demonstration that LMP1 is located in glycosphingolipid-rich domains of the cell membrane provided molecular evidence for the observed patching of LMP1 (11).
In the present study, we show that the C-terminal domain (CT) of LMP2A
is sufficient for association between LMP2A molecules as well as other
molecules carrying the LMP2A CT. This is the first demonstration that
the CT domain of LMP2A participates in molecular association between
LMP2A molecules. In addition, we show that two regions of the CT domain
are dispensable for LMP2A association, amino acids (aa) 471 to 480 and
aa 495 to 497. Also, our experiments show that the cysteine-rich
repeats between aa 471 and 480 are targets of palmitoylation, although
the localization of LMP2A to glycosphingolipid-rich raft domains in the
membrane does not require C-terminal palmitoylation.
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MATERIALS AND METHODS |
Cells, expression constructs, DNA transfections, and viral gene
transduction.
HEK 293 cells are human embryonic kidney cells
transformed by the adenovirus type 5 E1A and E1B genes
(17). A cDNA clone, pSP64-23TP carrying the LMP2A gene
from the B95-8 strain of EBV was generously donated by P. J. Farrell (23). A retroviral vector, pLXPOP, was used to
express the LMP2A. This was constructed from the pLNPOX vector
(25) by inserting the puromycin resistance gene in the
HindIII site following the poliovirus 5' untranslated region, destroying the BamHI site preceding the 5'
long terminal repeat by Klenow fill and recircularization and replacing
the Tn5 aminoglycoside 3' phosphotransferase (Neo) gene with
a multilinker with the sequence
5'-GAATTCACCGGTCGACGTACGGATCCTTAATTAAGCTTATTTAAATTCGAAAGATCTGTTTAAACTCGAG-3' (G. Winberg and R. Reynolds, unpublished data). The
HindIII-to-NsiI fragment from pSP64-23TP was
subsequently cloned into the HindIII and
BamHI sites of pLXPOP. The rat CD2 (42) was
adapted by PCR, and aa 1 through 225 (Phe) were cloned into the
EcoRI and BamHI sites of pBKCMV-Sfv (modified
from pBKCMV; Stratagene, La Jolla, Calif.), with the amino acids Gly
and Ile added in the BamHI site between Phe 224 of the CD2
sequence and the 27-aa LMP2 C terminus. Transfections of DNA from
expression plasmids and recombinant retrovirus constructs were done by
a modified CaPO4 technique (9),
using piperazine-N,N'-bis(2-ethanesulfonic acid)
(PIPES) for buffering instead of
N,N-bis(2-hydroxyethyl)-2-ethanesulfonic acid
(BES) or using polyethyleneimine precipitation as follows. For a
10-cm-diameter dish of 50% confluent cells, to 66 µl of H2O was added 12 µl of 50% glucose, 24 µl of
plasmid DNA (1 mg/ml), and finally, 18 µl of a 50 mM solution of
25-kDa polyethyleneimine (catalog no. 40872-7; Aldrich, Stockholm,
Sweden) in water at pH 7.0. The mixture was diluted into 2 ml of growth
medium and then added to 10 ml of medium in the dish. Supernatant from
the PG13 packaging cell line (26) was filtered through
0.45-µm-pore-size Tuffryn syringe filters (Pall-Gelman, Pall
Corporation, Ann Arbor, Mich.) and added to HEK 293 cells in the
presence of 8 µg of hexadimethrine bromide (Sigma, St. Louis, Mo.)
per ml. The LMP2A-expressing clone C4, as well as the 293P vector
control cells, was selected in 2 µg of puromycin (Sigma) per ml after
retroviral infection. Clone 3-5, expressing the CD2-LMP2 CT chimeric
protein, was selected in 400 µg of G418 (Gibco-BRL, Life Technologies
AB, Stockholm, Sweden) per ml after transfection. Expression in
individual clones was tested by immunoblotting.
Construction of CT mutants of the CD2-LMP2 CT chimera and of
full-length LMP2A.
Since the LMP2 C terminus is merely 27 aa, or
81 bp, all mutations were incorporated into PCR primers and the
C-terminal fragment was ligated into the pBKCMV-Sfv vector between the
BamHI site following residue 225 of rat CD2
(42) and the ClaI site at the end of the linker
in pBKCMVSfv. The CD2-LMP2 CT chimeric construct is 234 aa (not
including the N-terminal signal peptide of CD2), but the protein
migrates at about 40 kDa in sodium dodecyl sulfate (SDS) polyacrylamide
gels, presumably as a result of glycosylation of the CD2 exodomain.
Mutant constructs were verified by sequencing using the Big Dye
terminator system (Perkin-Elmer, Stockholm, Sweden). The amino acid
sequences of the CT mutants used are listed in Table
1. Of these mutants, the 
Cys, NTV, and KMN CT mutants were also built back into full-length LMP2A.
GST fusion proteins. The C-terminal domain of wild-type (wt) LMP2A was
amplified with a 5'
EcoRI site in frame with the
glutathione-
S-transferase
(GST) open reading frame in the
pGEX4-T-3 GST expression vector
(Amersham Pharmacia Biotech, Uppsala,
Sweden) and with a 3'
BamHI
site following the termination
codon of LMP2A. The
NTV and E6
Ter mutants were fused to the GST
protein in a similar fashion.
The DNA sequences of the constructs were
verified by dye terminator
sequencing (Big Dye; Perkin-Elmer), and
expression was induced
in 100-ml cultures of
Escherichia
coli BL-21 cells (CGSC, New
Haven, Conn.) at an optical density at
600 nm of 0.6, by addition
of
isopropyl-
-
D-thiogalactopyranoside (IPTG) to a
final concentration
of 1 mM, followed by a 2-h incubation at 37°C.
The pelleted cells
were resuspended in 2.5 ml of phosphate-buffered
saline-1% Triton
X-100 and sonicated with cooling until the lysate
cleared. After
removal of cell debris by centrifugation at 14,000 rpm
in an Eppendorf
5417R centrifuge (Eppendorf-Netheler-Hinz GmbH,
Hamburg, Germany)
for 30 min at 4°C, 0.5 ml of a 50% suspension of
glutathione-Sepharose
(Amersham Pharmacia Biotech) was added to the
cleared lysates
and incubated for 30 min at 4°C. Before use, the GST
beads were
washed three times in 1% NP-40 lysis buffer (50 mM Tris-HCl
[pH
8.0], 150 mM NaCl, 1% NP-40). GST pull-downs were performed by
incubating 100 µl of a 10% suspension of GST beads with 1 ml of
lysates from 10
7 LMP2A-expressing C4 cells or
control 293 cells for 1 h at 4°C,
followed by three washes in
1% NP-40 lysis buffer. Bound proteins
were released from the beads by
boiling for 5 min at 100°C in
50 µl of SDS sample buffer, of which
25 µl was separated by polyacrylamide
gel electrophoresis (PAGE).
SDS-PAGE (
21), transfer to polyvinylidene
difluoride
(PVDF) filters, and detection of LMP2A and hDlg proteins
on the filters
using specific antibodies followed standard procedures
(
18).
Antibodies, immunofluorescence, immunoprecipitations, and
immunoblots.
The rat anti-LMP2A MAbs 8C3, 14B7, and 4E11
(14) were purchased from ITN GmbH, Neuherberg, Germany.
The anti-rat CD2 hybridoma OX34 was purchased from American Type
Culture Collection, and the MAb was purified from culture supernatant
by Protein G Sepharose (Amersham Pharmacia Biotech) chromatography. For
use in immunoprecipitation, the LMP2A and CD2 MAbs were covalently
coupled to CNBr-activated Sepharose CL-4B (Pharmacia Amersham Biotech)
as previously described (18). Immunoprecipitations and
immunoblotting were performed using standard techniques, with
radioimmunoprecipitation assay (RIPA) buffer (18), for
solubilizing of cellular proteins. In short, 10 µl of a 10%
suspension of antibody beads was added to 1 ml of lysate from
107 transfected or stably antigen-expressing
cells. After three washes in RIPA buffer, captured antigens were
released from the beads by boiling in SDS sample buffer and separated
by SDS-PAGE as described above. Peroxidase-labeled anti-rat
immunoglobulin G (IgG) (heavy plus light chains [H+L]) (P0450; Dako
A/S, Glostrup, Denmark), anti mouse IgG (H+L) (PI-2000), anti-goat IgG
(H+L) (PI-9500), and anti-rabbit IgG (H+L) (PI-1000) conjugates were
from Vector Laboratories (Burlingame, Calif.). Transferrin receptor
(sc-7088), hDlg-1 (sc-9961), and caveolin (sc-894) antibodies were from
Santa Cruz Biotechnology (Santa Cruz, Calif.).
Insolubilized antibodies to LMP2A and rat CD2 were used in excess over
the antigens in immunoprecipitations, since reprecipitation
did not
yield detectable protein on immunoblots. PVDF filters
(Millipore
Corporation, Bedford, Mass.) were used throughout for
immunoblotting,
and detection was done using a luminol-based detection
kit (ECL;
Amersham Life Science, Little Chalfont, Buckinghamshire,
United
Kingdom).
Metabolic labeling of LMP2A- and CD2-LMP2 CT-expressing cells
with [14C]palmitate or [3H]palmitate.
HEK 293 cells expressing LMP2A (clone C4), CD2-LMP2 C-terminal chimera
(clone 3-5), and vector control cells (293P) were grown to 60 to 70%
confluency in 10-cm-diameter dishes with Iscove's modified Eagle's
medium and 5% fetal bovine serum. Labeling was in fresh medium with
the addition of 0.37 MBq of [14C]palmitic acid
per ml for 6 h at 37°C, 5% CO2. In total,
each plate received 3 ml of medium with a total of 1.11 MBq of
[U-14C]palmitic acid (CFB37; Amersham Pharmacia
Biotech). Labeling with [3H]palmitic acid was
performed for 4 h at 37°C in 2 ml of medium using a total of 37 MBq per plate of
[9,10(n)-3H]palmitic acid (TRK 909;
Amersham Pharmacia Biotech). After labeling, cells were lysed on ice in
RIPA buffer and subjected to immunoprecipitation (18)
using immobilized 8C3, 14B7, and 4E11 rat anti-LMP2A MAbs for lysates
from LMP2A-expressing cells and using immobilized anti-CD2 MAb OX34 for
the CD2-LMP2 CT-expressing 3-5 cells. Caveolin was immunoprecipitated
with the sc-894 antibody (Santa Cruz Biotechnology), while the hDlg
protein was specifically precipitated from labeled control 293 cells
using the GST-ETQV fusion protein (as described above). The
immunoprecipitates were separated by SDS-PAGE. The proteins were
transferred to PVDF membranes, and the specific proteins were detected
by immunoblotting. Following this, radiolabeled proteins were detected
by autofluorography on preflashed film. The dry filters were immersed
for 10 min in 22% (wt/vol) 2,5-diphenyloxazole in dimethyl sulfoxide.
After precipitating the 2,5-diphenyloxazole in water, the filters were
dried and exposed to X-ray film at 
70°C as described previously
(18).
Membrane fractionation in Triton X-100 flotation gradients.
Cell lysis was in 1 ml of TXNE (50 mM Tris-HCl [pH 7.4], 150 mM NaCl,
5 mM EDTA, 0.1% Triton X-100), with 10 µg of pepstatin A (Sigma) per
ml and protease inhibitors (Complete; Roche Diagnostic Systems,
Mannheim, Germany) at 4°C for a 10-cm-diameter plate of HEK293,
essentially as described previously (6). Optiprep (Nycomed
A/S, Oslo, Norway) gradients were made in three steps: the bottom step,
containing the cell lysate, was 35% Optiprep (1.2 ml); the middle step
was 30% Optiprep (3.1 ml); and the top step was 0.5 ml of TXNE.
Gradients were centrifuged at 40,000 rpm for 20 h at 4°C in the
SW50Ti rotor (Beckman). Three fractions were harvested: 1 ml from the
top fraction, 1 ml from the middle fraction, and 1 ml from the bottom
fraction. To ensure quantitative recovery of proteins, the fractions
were precipitated with 10% trichloroacetic acid in the presence of 200 µg of insulin per ml as described previously (33). The
protein pellets were washed by vortexing with 1 ml of 20°C acetone
to remove traces of trichloroacetic acid, before being dissolved in SDS
sample buffer (21).
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RESULTS |
Association between LMP2A and heterologous transmembrane molecules
depends on the presence of a clustering signal in the CT of LMP2A.
Previously, no functional role was defined for the CT of the LMP2
proteins; however, it contains a number of amino acid motifs that have
similarity to functional motifs in other proteins. The cysteine-rich
repeat (RCCRYCCYYC) near the membrane could be a target for
acylation or could mediate protein-protein interactions through metal
chelates; the C-terminal valine motif (NTV) is reminiscent of motifs
that bind PDZ domains; and the glutamic acid- and proline-rich motif
(ESEERPPTPY) is reminiscent of a similar motif in the N-terminal exon
of LMP2A (EERSNEEPPPPY), which was shown by us and others to mediate
binding to a WW domain from several members of a HECT protein family of
E3 ubiquitin ligases (20, 43).
To search for functional properties of the CT, we made chimeric
expression plasmids where the 27-aa C-terminal domain shared
between
LMP2A and LMP2B was fused to the transmembrane and extracellular
domains of rat CD2 (
42). The two cysteines on the
cytoplasmic
side of the 25-aa CD2 transmembrane domain were not
included in
the construct. The CD2 chimeric protein was highly
expressed in
293
cells.
Expressing these CD2 chimeric proteins in the LMP2A-expressing cell
line C4, we noticed that the CD2 chimera was coimmunoprecipitated
with
LMP2A. Our initial hypothesis was that this might be mediated
either by
protein-protein interactions mediated by the cysteine-rich
motif or by
the binding of a scaffolding protein containing PDZ
domains to the
C-terminal valine
motif.
To resolve this question, we created a set of mutants in the CD2
C-terminal chimera and investigated whether they would
coimmunoprecipitate
with LMP2A after transfection in the
LMP2A-expressing cell line
C4. The mutants used are shown in Table
1,
and the results obtained
with these mutants are shown in Fig.
1. In the experiment
illustrated
in Fig.
1A, immunoprecipitates from C4 cells coexpressing
CD2
chimeras with mutant LMP2 C termini were immunoblotted with the
OX34 MAb against CD2. Surprisingly, both the cysteine-rich repeat
and
the terminal valine motif were dispensable for coimmunoprecipitation
of
the CD2 chimera with LMP2A (Fig.
1A, lanes 4 and 8). As shown
in Table
1, the cysteine-rich motif was replaced by the lysine
and arginine-rich
membrane anchor of CD2, while the C-terminal
amino acids NTV were
simply deleted.
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FIG. 1.
Coimmunoprecipitation of CD2-LMP2 CT mutant chimeras
with LMP2A. All CD2-LMP2A chimeras were transiently transfected into
the stably LMP2A expressing C4 cell line and lysates were
immunoprecipitated with the three rat-anti-LMP2A MAbs 8C3, 14B7 and
4E11 coupled to Sepharose beads (see M&M). Captured antigens were
electrophoretically separated, transferred to PVDF membranes and probed
with the OX34 anti-CD2 MAb (A), to detect the presence of the chimeric
proteins in the LMP2A immunoprecipitates. (B) Whole cell lysates from
the transfected C4 cells were probed with the OX34 antibody to
determine the relative expression of the chimeric CD2 proteins in the
transfected C4 cells. The structure of the 27-aa C-terminal sequence in
each wt and mutant CD2 chimera, as well as the nomenclature of the
mutants, is explained in Table 1. Each lane contains lysate from
105 cells. (C) Filters with the LMP2A immunoprecipitates
were probed with a mixture of the three LMP2A-reactive MAbs to
demonstrate that the immunoprecipitates from the C4 cells contained
LMP2A. Lane 1 in the three panels is lysate from the LMP2A-negative,
CD2 LMP2A CT-expressing cell line 3-5, to show that CD2 is not
precipitated unspecifically with the LMP2A MAbs.
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We also investigated whether binding of a putative PDZ-domain protein
might be regulated by phosphorylation of the penultimate
threonine
(Fig.
1A, lanes 2 and 3) and whether phosphorylation
of the tyrosine in
the context of the proline motif PPTPY might
be required for the
association of CD2 chimeras with LMP2A (lane
6). Mutation of these
hydroxyamino acids did not abolish binding
to LMP2A, but substituting
the three terminal amino acids NTV
with KMN (lane 9) did inhibit
binding. Substituting consensus
sequences for PDZ proteins, one with
terminal ETQV from the HPV16
E6 protein and one with a terminal
isoleucine instead of valine,
gave two mutants which were both active
in binding LMP2A (lanes
5 and 10). In all experiments, the expressions
of both LMP2A and
the CD2 chimeras were similar between samples, as
demonstrated
for the CD2 chimeric proteins in Fig.
1B, showing
whole-cell lysates
from the transfected cells immunoblotted with the
OX34 MAb against
CD2, and for LMP2A in Fig.
1C, which shows an
immunoblot of immunoprecipitated
LMP2A from the CD2-transfected C4
cells. Lane 1 is a lysate from
the CD2-LMP2 CT-expressing cell line
3-5, showing that the CD2
chimera is not precipitated by the rat-anti
LMP2A MAbs 8C3, 14B7,
and 4E11 (
14). In the
coimmunoprecipitations shown in Fig.
1,
the CD2 constructs are
expressed in excess over LMP2A (see also
the radioimmunoprecipitation
experiment illustrated in Fig.
4A).
Moreover, LMP2A is quantitatively
precipitated from the cell lysates,
while only a fraction of the
available CD2 constructs was coimmunoprecipitated
with LMP2A, since a
second round of immunoprecipitation with LMP2A
antibodies did not bring
down additional LMP2A protein, while
reprecipitation with CD2
antibodies recovered residual CD2
construct.
The C-terminal clustering signal in the LMP2 C-terminal domain does
not require membrane association.
To rule out the possibility that
association of CD2 chimeric constructs with LMP2A might depend on
interactions between the transmembrane domains of LMP2A and CD2, we
decided to test whether LMP2A might also associate with a GST
fusion protein carrying the wt LMP2 CT domain. Figure
2 shows that this is
the case and, in addition, that the CT domain with deletion of the
terminal NTV motif is also active in the GST pull-downs of LMP2A (Fig. 2A). Remarkably, the GST construct carrying the mutation with terminal
ETQV pulls down not only LMP2A but also hDlg, in keeping with its
function in the HPV16 E6 protein. Figure 2B shows that the ETQV
construct pulls down hDlg from control 293 cells while GST protein
alone is inactive. These experiments demonstrate that the association
between LMP2A and the C-terminal domain of LMP2 is independent of
hydrophobic effects from transmembrane domains. This experiment also
shows that the sequences required for association of LMP2A with the
LMP2 CT domain are separate from those involved in binding a putative
PDZ protein to the C-terminal valine motif, since both proteins can
bind to the C terminus.
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FIG. 2.
GST pull-downs of LMP2A and hDlg. Lysates from
LMP2A-expressing C4 cells or control 293 cells were incubated
with GST fusion proteins containing the wt and two mutant LMP2 C
termini. (A) GST fusion proteins with the wt or NTV mutant pull
down LMP2A but not hDlg from C4 cells, while the GST fusion protein
with the HPV16 E6 C terminus (ETQV) pulls down both LMP2A and hDlg. (B)
The GST-ETQV CT construct is shown to pull down hDlg from the LMP2A
negative control cell 293, while the GST protein alone pulls down
neither LMP2A nor hDlg from the C4 cell line. This shows that the
binding site for the PDZ protein is physically separate from that of
LMP2A. The two immunoblots in each panel were first blotted with hDlg
antibody, and then they were stripped and reblotted with the anti-LMP2A
MAbs.
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Molecular association between the C-terminal clustering
domains.
To resolve the question as to what part of wt LMP2A
associates with the CD2- and GST-fusion proteins used in the above
experiments, we performed pull-down experiments with the GST-LMP2CT
fusion protein from lysates of the 3-4 cell line, which constitutively expresses the CD2-LMP2CT construct, from the C4 cell line expressing the wt LMP2A protein, and from 293 cells stably expressing the chimeric
CD38 transmembrane protein 3Tm (43), carrying the LMP2A N-terminal exon in the appropriate orientation of a type II membrane protein. Figure 3 shows that the
C-terminal domain of LMP2A can mediate association with another
C-terminal domain, and that no other sequences from LMP2A are required
for this interaction (Fig. 3A). It is conceivable that this association
between C-terminal domains is not a direct interaction but is mediated
by an as yet unidentified adapter protein.
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FIG. 3.
Interactions of the isolated C-terminal domain of LMP2
with membrane bound C- or N-terminal domains of LMP2A. (A) Immunoblots
with the OX34 MAb, directed against rat CD2. The top panel shows GST
pull-downs from lysates of the stable expressing cell lines indicated
above the figure, using the GST-LMP2 CT fusion protein, while the lower
panel shows expression of proteins in whole-cell lysates (WCL).
Approximately 2% of each WCL was loaded on the gel. (B) Immunoblots in
panel A were stripped and reprobed with MAb directed against the
N-terminal domain of LMP2A to detect whether the C-terminal
domain associates with the N-terminal domain of LMP2A (see Materials
and Methods).
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While the wt LMP2A protein clearly associates with the GST-LMP2CT
construct (Fig.
3B), we were unable to detect association
between the
GST construct and the N-terminal exon of LMP2A in
the background of the
3Tm construct. The secondary structure of
the LMP2A N-terminal domain
in the context of the chimeric 3Tm
construct might, however, deviate
sufficiently from that of the
wt LMP2A molecule to prevent its
association with the C-terminal
sequence in the GST fusion
protein.
The C-terminal cysteine residues are the major target of LMP2A
palmitoylation.
LMP2A is an integral transmembrane protein of 497 aa with type III topology, with intracellular N and C termini,
tentatively assigned 12 transmembrane domains. The C-terminal
domain is merely 27 aa in length and has a prominent cysteine
repeat interspersed with tyrosines and arginines located at the
junction between the last transmembrane and the intracellular domain.
The structure is highly conserved between the LMP2A proteins of
gammaherpesviruses EBV (human herpesvirus 4), herpesvirus papio
(baboon), and ceropithecine herpesvirus 15 (rhesus monkey).
A recent paper reports that LMP2A is palmitoylated (
19).
In the experiments described above we established that the C-terminal
cysteine repeats are dispensable for protein-protein association
between LMP2A and CD2 chimeras carrying the LMP2 CT domain (Fig.
1A,
lane 4). To clarify whether the C-terminal cysteine repeats
are targets
of this palmitoylation, we performed metabolic labeling,
with
[
14C]palmitic acid or
[
3H] palmitic acid, of 293 cells expressing wt
LMP2A, LMP2A
Cys
(where the cysteine repeats in the CT were
replaced with the arginine-
and lysine-rich membrane anchor from the
CD2 molecule), and finally,
a CD2-LMP2 CT chimera carrying the wt LMP2A
CT domain. The results
of labeling experiments using
[
14C]palmitic acid or
[
3H]palmitic acid did not
differ.
Figure
4A) shows an autofluorogram of a
PVDF filter with [
3H]palmitic acid labeled
immunoprecipitates from the labeled cell
lysates. The LMP2A
Cys and
LMP2A wt 16 lysates were from 293
cells, transfected with expression
constructs in the pBKCMV-Sfv
vector. The LMP2A wt C4 lysate was from
the C4 clone of 293 cells,
stably expressing LMP2A. There was no
significant difference in
palmitoylation between the two wt LMP2A
samples; however, the
Cys mutation showed no labeling with
palmitate, although the
expressions of the three full-length LMP2A
constructs were found
to be similar by immunoblotting (Fig.
4B). The
strong palmitoylation
of the CD2-LMP2 CT chimera (Fig.
4A, lane 4) is
explained by a
very high expression level of this construct in the
stably expressing
293 cell line 3-5. Palmitoylation of the raft protein
caveolin
is shown in lane 5, and hDlg1 was unlabeled, although its
expression
was detected by immunoblotting (Fig.
4C, lane 6), indicating
that
the label was incorporated in the form of palmitate and not as
recycled
14C or
3H from
metabolized lipid. The failure to detect palmitate label
in the LMP2A
Cys construct indicates that acylation of cysteine
residues outside
the C-terminal domain of LMP2A must be low compared
to the C-terminal
cysteines. The detection limit can be roughly
estimated by comparison
to the endogenously expressed caveolin
(lane 5). Caveolin is
irreversibly palmitoylated posttranslationally
(
31) on at
least two of the three juxtamembrane cysteines in
its C terminus
(
41) to allow its raft association and cholesterol
transport. Therefore, it is reasonable to assume that a single
acylated
cysteine outside the C-terminal domain might remain undetected.
It is
also worth mentioning that the two juxtamembrane cysteines
in the
cytosolic part of the wt CD2 molecule were excluded from
the constructs
used here, so palmitoylation of the CD2-LMP2A CT
chimera depends solely
on palmitoylation of one or more of the
five cysteines in the LMP2 CT.
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|
FIG. 4.
Metabolic labeling of LMP2A and CD2-LMP2CT with
[3H]palmitate. (A) Autofluorogram of a PVDF filter with
appropriate immunoprecipitates from the labeled cell lysates. Lanes: 1 and 3, immunoprecipitates of the LMP2A Cys mutant and the wt LMP2A
after transient transfection into 293 cells; 2, LMP2A immunoprecipitate
from the constitutively LMP2A expressing cell line C4; 4, CD2
immunoprecipitate from the stable cell line 3-5, expressing the
CD2-LMP2 CT construct. The caveolin (lane 5) and hDlg1 (lane 6)
immunoprecipitates represent expression of the respective endogenous
proteins in control 293 cells. (B) LMP2A immunoblot of the same filter
as in panel A, demonstrating that all three LMP2A constructs were
expressed. (C) Same filter as in panel A, after stripping and reprobing
with hDlg antibody. Immunoblots of CD2 and caveolin immunoprecipitates
on the filter in panel A are not shown, since the autofluorogram shows
that label was incorporated into these proteins.
|
|
Localization of LMP2A in a Triton X-100-insoluble glycolipid-rich
membrane domain does not depend on C-terminal palmitoylation.
Since acylation is often a signal for apical sorting into
glycolipid-rich rafts, it was of interest to investigate whether the
raft localization of LMP2A (12) was dependent on
palmitoylation. It was also important to establish whether the mutant
CD2-CT chimeric constructs used to demonstrate association between the
CT domain and full-length LMP2A were expressed in the same membrane
compartment as LMP2A. Figure 5 shows the
results of Optiprep flotation gradients. Endogenous transferrin
receptor and caveolin in lysates of 293P vector control cells (Fig. 5C
and D, respectively) were used as markers for the solubilized and
Triton X-100-insoluble membrane compartments, respectively
(6). The endogenous CD2 in Jurkat T cells also serves as a
control since CD2 is located in rafts (45). In Fig. 5A, wt
and three LMP2A mutants are shown. The Cys mutant was of interest
because it lacks cysteines in the CT domain, and thus lacks C-terminal
palmitoylation (Fig. 4, lane 1). The NTV mutant, which lacks the
PDZ-like terminal valine motif, was included because it might fail to
localize to rafts if clustering by a PDZ protein would be essential for
apical sorting (28, 29). The KMN CT mutant was
investigated because its failure to cluster with other CT constructs
(Fig. 1) might depend on inappropriate expression in the membrane. In
all cases, however, the full-length LMP2A constructs were recovered
from the Triton X-100-insoluble top fraction of the gradients (Fig.
4A).
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|
FIG. 5.
Optiprep gradient fractionation of different membrane
compartments from HEK 293 cells expressing either LMP2A (A) or CD2-LMP2
CT chimeric membrane proteins (B). Three fractions were collected, one
each from the top, middle, and bottom layers of the gradient (indicated
by the letters t, m, and b above the left gradient shown in panel A).
The direction of flotation of the lighter membrane fraction, not
solubilized in Triton X-100, is shown with an arrow, pointing from the
bottom to the top of the gradient at the top left of panel A. Fractions
were collected, treated as described in Materials and Methods, and
blotted on PVDF membranes for immunoblotting. (A) Distribution of LMP2A
protein in the gradients is shown for the LMP2A wild type and the Cys, NTV, and KMN CT mutants in the full-length LMP2A background.
(B) Distribution of CD2-LMP2A CT constructs between Triton
X-100-soluble (bottom) and -insoluble (top) membrane fractions is
shown. A lysate from the human T-cell line Jurkat was included, to
demonstrate that the native CD2 molecule distributes similarly to the
chimeric constructs used in this study. (C and D) Locations of two
control proteins, endogenously expressed in the 293 cells; caveolin
which is a marker for the detergent-insoluble glycolipid-enriched
membranes (rafts) (C) and transferrin receptor, which is known to
distribute in the Triton X-100 soluble phosphatidyl-etanolamine rich
part of the membrane (D). Immunoblotting was performed with the
appropriate antibodies as described in Materials and Methods.
|
|
The CD2-CT chimeric constructs shown in Fig.
5B are also located
in the top fraction of the gradients, showing that they are
appropriately expressed in the same membrane compartment as LMP2A
and
that the failure of the CD2-LMP2 KMN CT construct to associate
with wt
LMP2A (Fig.
1) is not a result of expression in a separate
membrane
compartment.
The raft association of the CD2 constructs is likely to depend on
properties of the CD2 backbone in these constructs (including
the
transmembrane domain), since the native CD2 molecule is located
in
rafts (Fig.
4B). A fine punctate membrane-staining pattern
in 293 cells
expressing the CD2 constructs also supports the raft
localization (data
not
shown).
| |
DISCUSSION |
It is known that molecular clustering is required for activation
of the LMP2A N-terminal domain by tyrosine phosphorylation. In the
initial demonstration of signal transduction activity by the LMP2A
N-terminal domain (2), antibody ligation of a CD8-LMP2A N-terminal chimera resulted in calcium signals and interleukin 2 production by IIA1.6 lymphoma B cells, while the nonligated chimeric
molecule was inactive. In addition, our demonstration that the E3
ubiquitin ligase binds to nonphosphorylated tyrosines in the two PPPPY
motifs in the LMP2A N-terminal exon relied on the demonstration that
AIP4 binds to a CD38-LMP2A chimeric transmembrane construct (3Tm),
where all tyrosines remain in the unphosphorylated state as long as the
construct is not clustered by antibody to the CD38 exodomain
(43). Since wt LMP2A is constitutively phosphorylated on
tyrosine 112 (16), it is reasonable to hypothesize that
LMP2A molecules spontaneously associate in the membrane. This could be
the result of direct interaction between LMP2A molecules or be mediated
by a scaffolding protein (32) as described for the cystic
fibrosis transmembrane conductance receptor and many other ion channels
(5). One purpose of this investigation was to decide if
and by what mechanism association between LMP2A molecules might take
place. Our finding is that transmembrane chimeras carrying the rat CD2
exodomain and transmembrane domain fused to the LMP2 CT domain as well
as GST fusion proteins carrying the LMP2CT domain interact with wt
LMP2A. Furthermore, we show that the C-terminal domain is capable of
association with itself, since the CD2-LMP2CT chimera efficiently
interacts with the GST-LMP2CT fusion protein. Our mutation analysis
shows that neither the cysteine-rich repeat nor the PDZ-like motif at
the LMP2 C terminus is essential for this protein-protein interaction.
If LMP2A molecules required a PDZ-containing scaffolding protein for
clustering, then such a protein would be likely to bind to the terminal
valine motif. However, this protein is not hDlg, since hDlg cannot be
detected on an immunoblot of the GST-wt CT pull-down in Fig. 2A. On the
other hand, the hDlg binding to the GST-ETQV CT construct, shown in the
same immunoblot, would then block binding of the hypothetical PDZ
scaffolding protein that normally would cluster LMP2A molecules. This
would also prevent binding of LMP2A. Since both hDlg and LMP2A bind to
the ETQV construct, and since LMP2A also binds to the GST NTV
construct, it is unlikely that the terminal NTV motif is involved in
LMP2A clustering. Instead, it is probable that there is a protein
interaction motif located between the cysteine-rich repeat and the
terminal NTV tripeptide. This would correspond to all or part of the
sequence LTLESEERPPTPYR, located between the cysteine-rich repeat and
the terminal NTV tripeptide.
This prompted us to ask whether the cysteine-rich repeats might have a
different function. We demonstrate that LMP2A and the corresponding CD2
chimera are palmitoylated, while in a mutant LMP2A ( Cys), with an
arginine- and lysine-rich membrane anchor in place of the cysteine-rich
repeat, palmitoylation was not detected. This shows that the C-terminal
cysteines are the major site of LMP2A palmitoylation. As previously
described, palmitoylation of membrane proteins may regulate their rate
of internalization (1), which may be relevant in the
context of recent studies indicating that LMP2A interferes with
internalization of antigen-activated B-cell receptor (12).
Our studies of LMP2A localization in rafts (38) also
confirm previous findings (12, 19) and demonstrate,
additionally, that C-terminal LMP2A palmitoylation is
nonessential for the localization of LMP2A in detergent-insoluble
glycolipid-enriched membrane microdomains (rafts). These
experiments also verify that the molecular interactions between LMP2A and C-terminal mutants in the CD2 chimeric background take place between proteins that are expressed in the same membrane compartment. This shows, specifically, that the failure of the CD2-KMN
CT mutant to associate with LMP2A is not due to a defect in raft association.
Figure 6A, B, and C illustrate our
findings regarding molecular association of LMP2A molecules. In Fig.
6D, finally, we show a model of the hypothetical interaction between
LMP2 proteins suggested by our demonstration of a C-terminal
association motif. The demonstration of this interaction is
biologically meaningful only if the existence of the LMP2B protein can
be shown in EBV-infected cells. We are currently using the GST-LMP2CT
fusion protein to isolate this protein from B cells in latency III and
from EBV-positive NPC cells in culture.
View larger version (29K):
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|
FIG. 6.
Models of C-terminal interactions between LMP2 proteins.
(A) Association between LMP2A and the CD2 chimeric transmembrane
proteins with the LMP2 C-terminal domain. (B) Interaction of the
GST-LMP2 CT constructs. (C) The interactions involve two C-terminal
domains, since the GST-LMP2A CT fusion protein can pull down the
CD2-LMP2A C-terminal chimera from cell lysates of 3-5 cells. While we
show that these interactions occur as tail-tail interactions, we cannot
exclude that head-tail interactions might also occur. (D) Hypothetical
interaction between LMP2 proteins through their shared C-terminal
domains.
|
|
Our present finding that a C-terminal motif, hypothetically located
between aa 481 and 494, is sufficient for the physical association
between LMP2A and heterologous transmembrane molecules or soluble GST
fusion proteins carrying this motif may help explain how LMP2A is
normally kept in a clustered, constitutively active state and may be of
particular importance for understanding the role of the LMP2B in
regulating the latency state of EBV-carrying cells. Although the
existence of the LMP2B protein remains to be demonstrated, it has been
hypothesized that the stringent control of B-cell phenotype maintained
by LMP2A in type I latency might be relaxed as the cell progresses
through latency II and III, perhaps in part as a result of LMP2B
expression. The LMP2B protein, which lacks the N-terminal exon of
LMP2A, might cocluster with LMP2A and reduce the local concentration of
cellular proteins binding to the N-terminal exon of LMP2A. This would
reduce the effects of LMP2A on signal transduction in the B cell.
| |
ACKNOWLEDGMENTS |
This work was supported in part by grant No K1999-06X-012622-02B
from the Swedish Medical Research Council to G.W. and L.M., by grants
from the Swedish Cancer Society to I.E., and by grants from the
Canadian Institutes of Health Research and the National Cancer
Institute of Canada to T.P.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Karolinska
Institutet, MTC, P.O. Box 280, SE-171 77 Stockholm, Sweden. Phone: 468 457 2610; 468 728 6749. Fax: 468 31 9470. E-mail:
Gosta.Winberg{at}mtc.ki.se.
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Journal of Virology, November 2001, p. 10941-10949, Vol. 75, No. 22
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.22.10941-10949.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
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