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Journal of Virology, December 2001, p. 11781-11790, Vol. 75, No. 23
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.23.11781-11790.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Functional Cooperation of Epstein-Barr Virus
Nuclear Antigen 2 and the Survival Motor Neuron Protein in
Transactivation of the Viral LMP1 Promoter
Marc D.
Voss,1
Annette
Hille,1
Stephanie
Barth,1
Andreas
Spurk,1
Frank
Hennrich,1
Daniela
Holzer,1
Nikolaus
Mueller-Lantzsch,1
Elisabeth
Kremmer,2 and
Friedrich A.
Grässer1,*
Abteilung Virologie, Institut für
Medizinische Mikrobiologie und Hygiene, Universitätskliniken,
66421 Homburg/Saar,1 and Institut
für Molekulare Immunologie, GSF, 81377 Munich,2 Germany
Received 16 May 2001/Accepted 29 August 2001
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ABSTRACT |
Epstein-Barr virus nuclear antigen 2 (EBNA2) is essential for viral
transformation of B cells and transactivates cellular and viral target
genes by binding RBPJ
tethered to cognate promoter elements. EBNA2
interacts with the DEAD-box protein DP103 (DDX20/Gemin3), which in turn
is complexed to the survival motor neuron (SMN) protein. SMN is
implicated in RNA processing, but a role in transcriptional regulation
has also been suggested. Here, we show that DP103 and SMN are complexed
in B cells and that SMN coactivates the viral LMP promoter in the
presence of EBNA2 in reporter gene assays and in vivo. Subcellular
localization studies revealed that nuclear gems and/or coiled bodies
containing DP103 and SMN are targeted by EBNA2. Protein-protein
interaction experiments demonstrated that DP103 binds to SMN exon 6 and
that both EBNA2 and SMN interact with the C terminus of DP103.
Furthermore, a DP103 binding-deficient SMN mutant was released from
nuclear gems and/or coiled bodies and further enhanced coactivation. In
addition, impaired transactivation of a DP103 binding-deficient EBNA2
mutant was rescued by overexpression of SMN. Testing different promoter
constructs in luciferase assays showed that RBPJ is required but not
sufficient for coactivation by EBNA2 and SMN. Overall, our data suggest
that EBNA2 might target spliceosomal complexes by binding to DP103,
thereby releasing SMN which subsequently exerts a coactivational
function within the RNA-polymerase II transcription complex on the LMP1 promoter.
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INTRODUCTION |
The Epstein-Barr virus (EBV) causes infectious
mononucleosis and is linked to the genesis of several human
lymphoproliferative diseases (for a review, see reference
33). The EBV-encoded nuclear antigen 2 (EBNA2) is a viral
transactivator essential for EBV-induced transformation of resting
human B lymphocytes, by promoting the expression of the transforming
latent membrane proteins LMP1 and 2, the nuclear EBV Cp promoter-driven
EBNA proteins, and the cellular genes CD23 and c-fgr (for
review, see reference 15). EBNA2 does not bind directly to
DNA but exerts its function by interacting with the cellular proteins
RBPJ (CBF1) and, on the more complex LMP1 promoter, also Spi1
(PU.1), tethered to cognate response elements (12, 17, 20, 45,
46). Transcriptional activation is induced by binding of the
C-terminal acidic domain (5) to components of the basal
RNA polymerase II transcription machinery, such as RPA70, TAF40, TFIIB,
and TFIIH (38, 39), and recruitment of the coactivators
p300, CBP, and PCAF histone deacetylase (14, 41). In
addition, by attracting the hSWI/SNF complex (42, 43) and
targeting histone H1 (9, 34), EBNA2 likely promotes relief
of nucleosome-mediated gene repression.
We have recently shown that EBNA2 binds to DP103, a novel member of the
DEAD-box family of putative RNA helicases (10). DP103 is a
ubiquitously expressed 103-kDa phosphoprotein with an RNA-dependent
ATPase activity; its other functions, in particular with regard to its
interaction with EBNA2, remained unknown. While the work
presented here was in progress, an interaction of DP103 (alternatively
called Gemin3 [2]) and the survival motor neuron (SMN)
protein, and their respective murine homologues, were described in two
independent studies (1, 2).
SMN is part of a multiprotein complex containing SIP1, DP103 (Gemin3),
GIP1 (Gemin4), and several Sm proteins that is involved in the assembly
and nuclear regeneration of snRNPs and spliceosomes (2, 7, 25,
31). Both SMN and DP103 are localized in the cytoplasm and
distinct nuclear structures, described as coiled bodies and gems
(gemini of coiled bodies) (2, 21, 31). Mutations in the
SMN gene result in spinal muscular atrophy (SMA), a recessive
genetic disease with loss of 
-motor neurons in the spinal cord,
leading to muscle weakness and subsequent death. The SMN gene exists in
two inverted copies within the same chromosomal region on chromosome
5q13 (19). In most SMA patients, a mutated telomeric form
of the SMN gene results in a nonfunctional exon 7-deleted SMN, unable
to self-associate (22), which cannot be compensated by the
low amounts of full-length SMN protein expressed from the centromeric
allele (24). In a few cases of SMA, point mutations were
described which exchange amino acid (aa) 272 (Y272C) (19)
or aa 134 (E134K) (4), affecting a putative RNA binding tudor domain (26). Furthermore, knockout of the murine SMN
gene or its yeast homologue Yab8p resulted in a lethal phenotype
(11, 28, 35).
Interestingly, a role for SMN in transcriptional regulation has been
implicated, since SMN was shown to interact with the bovine
papillomavirus E2 transactivator and to coactivate an E2-responsive viral promoter (1, 36). Furthermore, Ou et al.
demonstrated that murine dp103 is also involved in transcriptional
regulation by negatively modulating the expression of steroidogenic
factor-1 (27). Finally, the SMN complex has recently been
shown to associate with the C-terminal domain (CTD) of RNA polymerase
II (30), although the functional consequences of this
interaction have not yet been elucidated.
Searching for DP103-associated cellular proteins by using the yeast
two-hybrid system, we also identified SMN as an interaction partner of
DP103. Here, we show that this interaction is also relevant in B cells
and that SMN is able to coactivate the viral LMP1 promoter in the
presence of EBNA2 in vitro and in vivo. Data obtained from analyzing
different EBNA2, DP103, and SMN mutants regarding their binding
domains, subcellular distribution, and influence on EBNA2-mediated
transactivation suggest that SMN is a novel factor involved in
EBNA2-mediated transactivation of the viral LMP1 promoter: by targeting
of DP103 within spliceosomal complexes, EBNA2 subsequently releases
transcriptionally active SMN, which functions as a coactivator, likely
within the RNA polymerase II transcription complex.
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MATERIALS AND METHODS |
Cell lines and antibodies.
Raji cells, derived from an
EBV-positive Burkitt's lymphoma, EBV-negative BJAB B-lymphoma cells,
and EBV-positive P3HR1 cells, harboring an EBNA2-deleted virus strain,
were maintained in RPMI 1640 supplemented with 10% fetal calf serum,
antibiotics and 1 mM sodium pyruvate as described previously
(10). Human HeLa and 293GP cells were maintained in
Dulbecco modified Eagle medium supplemented as described above.
Monoclonal antibodies (MAbs) 9A3 and 8H4 directed against DP103, MAb R3
directed against EBNA2, and MAb S12 directed against LMP1 have been
described (10, 16, 23). A polyclonal goat antiserum
directed against the N terminus of human SMN protein was purchased from
Santa Cruz Biochemicals; anti-
-actin MAb was obtained from Sigma.
Anti-SMN MAb 7B10 (25) was kindly provided by U. Fischer
(MPI für Biochemie, Martinsried, Germany). MAb 3F10 directed
against the hemagglutinin (HA)-epitope sequence YPYDVPDYA and
MAb 9E10 against the c-myc-epitope sequence EQKLISEEDL were from Roche
Molecular Biochemicals.
Plasmids.
DNA manipulations were carried out according to
standard procedures. pACT2 SMN wild type (WT) was derived from
a positive scoring yeast clone, subcloned into pGEM-T (pGEM-T SMN WT),
and sequenced. A WT SMN fragment was PCR amplified from from pACT2 SMN
WT by using primers EcoHASMN
(5'-GCGGAATTCCACCATGTACCCTTACGATGTACCGGATTACGCAGCGATGAGCAGCGGCGGCAGTGGT-3') and SMN3'XhoBam (5'-CGCGGATCCTCGAGCTGCTCTATGCCAGCA-3'),
EcoRI/BamHI digested, and ligated into pSG5
(Stratagene) to generate pSG5-HA SMN WT. Exon mutants of SMN (
Ex7,
Ex6/7, and Ex5-7) were PCR amplified from pACT2 SMN WT by using
5'-primer SMN5'Bam1 (5'-CGCGGATCCATGGCGATGAGCAGCGG-3') and the respective 3'-primers 3'SMNd7stop
(5'-CGCCTCGAGTTACATATAATAGCCAGT-3'), 3'SMNd6,7stop
(5'-CGCCTCGAGTTATGGTGGTCCAGAAGG-3'), and
3'SMNd5,6,7stop (5'-CGCCTCGAGTTACTTTCCTGGTCCCAG-3'). PCR
products were BamHI/XhoI digested and ligated
into PACT2 for yeast two-hybrid analysis. BglII fragments,
including the sequences encoding the HA tag from these pACT2
constructs, were ligated into pSG5 to generate the corresponding
pSG5-HA constructs. pSG5-myc SMN and pSG5-HA SMN N27 were
synthesized by PCR using the 5'-primer Myc5'EcoSMN
(5'-GCGGAATTCCATATGGAGCAAAAGCTAATATCGGAAGAAGATCTCGCGATGAGCAGCGGCGGCAGTGG-3') or Eco-HA-SMN27
(5'-GCGGAATTCCACCATGTACCCTTACGATGTACCGGATTACGCAGCGAGCGATGATTCTGACATTTGG-3') and 3'-primer SMN3'XhoBam
(5'-CGCGGATCCTCGAGCTGCTCTATGCCAGCA-3') and
ligation of the EcoRI/BamHI-digested fragments
into pSG5. Ligation of an NcoI/SalI fragment from
pGEM-T DP103 (10) into pACT2 resulted in pACT2 DP103.
pSG5-HA DP103 WT, 456-547, and 341-461 were generated by ligation
of a DP103 BglII fragment from the respective pACT2 DP103
mutants into pSG5. Point mutations (pSG5-HA SMN E134K and Y272C;
pSG55-HA DP103 and K112N) were introduced by site-directed mutagenesis
of the WT pSG5-HA constructs by using Pfu Turbo
DNA-Polymerase (Stratagene) and primers introducing the respective
mutation and a new, unique restriction site. For expression as enhanced
green fluorescence fusion protein (EGFP), an EBNA2
EcoRI/BglII fragment was cloned from pSG5 into
pEGFP-C1 (Clontech). A WT SMN fragment was synthesized by PCR from
pGEM-T SMN WT by using primers C1EGFP-SMN5'
(5'-GCGAATTCCATGGCGATGAGCAGCGGC-3') and
SMN3'XhoBam (see above), EcoR/BamHI digested, and
ligated into pEGFP-C1 (Clontech) to yield pEGFP-C1 SMN WT. pSG5-luc was generated by ligating a SalI/Bg II fragment to a
SalI/BglII-digested LL0 luciferase
plasmid (18), thereby replacing the LMP1 promoter by the
simian virus 40 promoter and a -globin intron. The EBNA2 mutants
pSG5 EBNA2 121-216 and pSG5 EBNA2 322 were generated by replacing an
internal M-ABA strain BamHI fragment of pSG5-EBNA2 WT by
BamHI fragments which were PCR amplified from pSG5 EBNA2 WT
or pAC EBNA2-HaeII1 (34) with the primers
BamHI213E25'
(5'-GCGGATCCGCCACCAAGGCCTACCCGTC-3') and
E2wtBglII3' (5'-AGATCTTACTGGATGGAGGGGCGA-3') or
the primers EcoXho5E2
(5'-GCCGAATTCTCGAGGCCATCATGCCTACATTCTATCTTGCGTTA-3') and BglXho-3E2
(5'-CGAAGATCTCGAGTTACTGGATGGAGGGGCGAGGTCT-3'). All constructs were sequenced by using the Biozym sequencing kit. pSG5
EBNA2 WT was a generous gift from M. Rowe (University of Wales,
Cardiff, United Kingdom). Luciferase constructs LL0 to LL9
(18) and pGa981-21 and pGa50-7 (37) were
kindly provided by G. Laux and U. Zimber-Strobl (GSF).
Yeast two-hybrid analysis.
For a review of the yeast
two-hybrid system, see Phizicky and Fields (32). The
complete open reading frame of DP103 was PCR amplified by using the
original isolate pGEM DP103 (10) and the primers
BglII5'DP103
(5'-GGAAGATCTGCCATGGCGGCGGCATTTGAAGC-3') and Sp6
(5'-TATTTAGGTGACACTATAG-3') and then
BglII/PstI digested and inserted into the
BamHI/PstI-digested vector pAS2-1 (Matchmaker Two-Hybrid System 2; Clontech) to generate vector pAS DP103 expressing a Gal4 DNA-binding domain fused to DP103. The expression of a fusion
protein with the appropriate size in the yeast strain Y190 was verified
by using the DP103-specific MAb 8H4. This construct was used to screen
a lymphocyte-derived cDNA library (Clontech Matchmaker Library;
Clontech). Resulting clones were segregated by using cycloheximide and
appropriate media and retested for specific binding by mating with
yeast containing either DP103 or an unspecific bait. Clones scoring
positive were rescued in Escherichia coli and sequenced with
the Biozym sequencing kit. Quantification of -galactosidase activity
was carried out by liquid culture assay by using ONPG
(o-nitrophenyl--D-galactopyranoside) according to the Clontech Matchmaker 2 protocol.
Immunoprecipitations.
For immunoprecipitation of endogenous
proteins, Raji cells were washed in phosphate-buffered saline (PBS),
extracted in lysis buffer (100 mM Tris-HCl [pH 8.0], 100 mM NaCl, 5 mM KCl, 0.5 mM MgCl2, 1 mM
CaCl2, 0.5% [vol/vol] Triton X-100, and
protease inhibitors), and incubated for 1 h at 4°C with
anti-DP103 MAb 9A3 or an irrelevant control MAb (anti-trpE 3A6)
absorbed to protein G-Sepharose (Pharmacia). Bound immune complexes
were washed 10 times (5 times with 1 M NaCl and five times without
NaCl) with radioimmunoprecipitation assay (RIPA) buffer (10 mM Tris-HCl
[pH 7.5], 0.5% [vol/vol] deoxycholate, 0.5% [vol/vol]
NP-40, 0.1% sodium dodecyl sulfate [SDS], 0.1 mM EDTA, and protease
inhibitors), released by boiling in gel loading buffer, and then
subjected to SDS-polyacrylamide gel electrophoresis (PAGE) and Western
blotting. Proteins were detected by using MAb 8H4 or anti-SMN-N serum
(Santa Cruz Biotechnology). For mapping of the SMN and DP103
interaction domains, 293GP cells were grown in 10-cm dishes and
transfected with HA-tagged SMN mutants or cotransfected with myc-tagged
WT SMN and HA-tagged DP103 mutants by the calcium phosphate method.
After growth for 36 to 48 h, cells were extracted in lysis buffer.
Supernatants were incubated with anti-HA MAb 3F10 or unspecific control
MAbs (anti-trpE 3A6 and anti-BDV p40 9C2) absorbed to protein
G-Sepharose for 1 h at 4°C. Bound complexes of endogenous DP103
and transfected HA-tagged SMN mutants were washed 10 times (5 times
with 1 M NaCl and five times without NaCl) with RIPA buffer; complexes
of transfected myc-tagged WT SMN and HA-tagged DP103 mutants were
washed two times in RIPA buffer (1 M NaCl) and four times in lysis
buffer. Proteins were separated by boiling with gel loading
buffer and then subjected to SDS-PAGE and Western blot analysis.
Transfection of B lymphocytes and luciferase assays.
BJAB
and P3HR1 cells were transfected by electroporation by using a Bio-Rad
Gene Pulser at 250 V and 950 µF, with slight modifications as
described previously (45). Briefly,
107 cells were washed once and resuspended in
0.25 ml of ice-cold RPMI 1640 without supplements and placed on
ice. Then, 4 µg of reporter plasmid, 10 µg of each respective
effector plasmid, and 2 µg of pEGFP-C1 (Clontech) were added.
Parental pSG5 vector (Stratagene) was used to adjust DNA amounts. After
electroporation, cells were kept on ice for 10 min, suspended in 10 ml
of RPMI with 20% fetal calf serum, and grown for 48 h. To
determine the transfection efficiency, 100 µl of the cells was fixed
and analyzed in a Becton Dickinson FACScan analyzer for EGFP-positive
cells, gated on the living population. The remainder of cells were
washed in PBS and lysed by three cycles of freeze-thawing in 250 mM
Tris-HCl (pH 7.8). The luciferase activity of the supernatants was
determined in a Lumat LB9501 (Berthold) by using the Promega luciferase
assay system (Promega) as recommended by the manufacturer.
Immunofluorescence.
Immunofluorescence analysis with HeLa or
BJAB cells was performed with slight modifications as described
previously (6). Briefly, HeLa cells grown on cover slides
in six-well plates were lipofected with 5 µg of DNA by SuperFect
(Qiagen) according to the manufacturer's protocol. BJAB cells were
electroporated with 10 µg of DNA as described above. After 24 h,
the cells were washed with PBS, fixed with 4% paraformaldehyde-PBS at
room temperature for 15 min, permeabilized with 0.2%Triton X-100-PBS
(2 min, 4°C), and blocked with 2% bovine serum albumin (BSA)-PBS
(15 min, 37°C). HA-tagged proteins were detected by using anti-HA MAb
3F10, and endogenous SMN protein was detected by using MAb 7B10,
diluted in 3 µg of BSA-PBS/ml (45 min, 37°C), and TRITC
(tetramethyl rhodamine isocyanate)-labeled anti-rat (Dianova) or
anti-mouse (Sigma) MAb in 3 µg of BSA-PBS/ml as secondary antibodies
(30 min, 37°C). Cover slides were mounted in
Elvanol and subjected to immunofluorescence microscopy by
using a Zeiss Axiovert 100 TV microscope and a Sony 3CCD camera (see
Fig. 3D). Confocal images were taken by using a Nikon Eclipse E600
micoscope equipped with a PCM 2000 confocal laser-scanning system and
analyzed by using Confocal Assistant 4.02 and use of Corel Photo Paint
and Draw version 8.0 software.
GenBank accession number.
The nomenclature committee
authorized by the human genome project (HUGO) proposed to rename the
DP103 gene to DDX20 in keeping with the guidelines for nomenclature of
DEAD/H-box proteins of putative RNA and DNA helicases (GenBank
accession no. NM_007204).
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RESULTS |
DP103 (DDX20/Gemin3) and the SMN protein interact in B cells.
Recently, we have shown that EBNA2 associates with the cellular
DEAD-box protein DP103 (10). Since the functional
consequences of this interaction remained unknown, we sought to
identify cellular proteins associating with DP103 in the yeast
two-hybrid system. The screening of a B-lymphocyte cDNA library with
full-length DP103 yielded nine individual clones: four containing the
complete SMN gene and the remaining five containing 5'-truncated SMN
genes (data not shown). This result was confirmed by an alternative experimental approach with data published while the present manuscript was in preparation (1, 2). Since EBV is a lymphotrophic virus, we sought to determine whether this interaction of DP103 and SMN
could also be detected in B lymphocytes. Therefore, both endogenous
proteins were coimmunoprecipitated from EBV-positive Raji lymphocytes
by using the DP103-specific MAb 9A3 (Fig.
1A). An irrelevant control MAb neither
precipitated DP103 nor coprecipitated SMN. Note that, due to the small
amount of total cell lysate used as input and the low affinity of the
goat anti SMN antibody, the amount of SMN in the input lane was below
the level of detection.
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FIG. 1.
(A) Interaction of DP103 and SMN in B lymphocytes.
Coimmunoprecipitations (IP) from Raji cell extracts were performed with
DP103-specific MAb 9A3 (IP: DP103 Ab) or an irrelevant control antibody
(anti-TrypE 3A6, IP: control Ab), followed by SDS-10% PAGE and
Western blotting. Precipitated proteins were detected with anti-SMN-N
serum (Santa Cruz Biochemicals) (left panel, WB: anti SMN) or
anti-DP103 MAb 8H4 (right panel, WB: anti DP103). The positions of SMN
and DP103 are indicated by arrows. Lanes designated Raji input
represent ca. 1% of unprecipitated Raji cell extract. The positions of
the molecular mass marker proteins are indicated on the left side (in
kilodaltons). (B) SMN coactivates the viral LMP1 promoter in the
presence of EBNA2. BJAB cells were transfected with luciferase reporter
constructs encoding positions  327/+40 (EBNA2 responsive) or 154/+40
(nonresponsive) of the LMP1 promoter (4 µg) and the indicated
combinations of pSG5 constructs encoding EBNA2 or HA-tagged SMN and
DP103 (10 µg). After 48 h, the cells were lysed by
freeze-thawing, and the luciferase activity was measured. The
transfection efficiency was determined by scanning the expression of
cotransfected pEGFP-C1 vector (2 µg) by FACS analysis prior to lysis
of the cells. For each experiment, luciferase values standardized for
transfection efficiency were calculated relative to the values obtained
by EBNA2 and the respective full-length promoter construct (set to
100%). Graphs represent the mean values of five independent
experiments (± the standard error of the mean [SEM]).
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SMN coactivates the viral LMP1 promoter in the presence of
EBNA2.
To elucidate the role of DP103 and SMN regarding the
function of EBNA2, the transactivation of its main target, the viral LMP1 promoter, was examined in EBV-negative BJAB lymphocytes. Coexpression of EBNA2 and SMN reproducibly increased EBNA2-mediated transactivation of a cotransfected full-length (327/+40) LMP1 promoter luciferase construct (LL0) (18) by almost
300% (Fig. 1B), relative to the values obtained by EBNA2 alone (set to
100%). This effect could further be titrated by coexpressing EBNA2 and increasing amounts of SMN (Fig. 2A),
indicating that SMN coactivates the viral LMP1 promoter in the presence
of EBNA2. However, coexpression of both SMN and DP103 in the presence
of EBNA2 resulted only in an increase of 150%. Furthermore,
coexpression of DP103 and EBNA2 slightly decreased EBNA2-mediated
transactivation to 75%. Note that in the absence of EBNA2 neither SMN,
DP103, nor both showed any effect. A truncated, EBNA2 nonresponsive
(154/+40) reporter construct (LL4) (18) served as a
negative control. Thus, SMN is capable of coactivating the LMP1
promoter in the presence of the viral transactivator EBNA2, resulting
in increased amounts of luciferase transcripts and protein.
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FIG. 2.
(A) Dose-dependent coactivation of the 327/+40 LMP1
promoter by coexpression of EBNA2 and increasing amounts of HA-tagged
SMN (indicated in micrograms). Assays were performed as described for
Fig. 1B. Graphs represent the mean values of three independent
experiments performed in duplicate (±SEM). (B) SMN increases
EBNA2-mediated induction of endogenous LMP1 protein. EBV-positive P3HR1
cells were transfected with pSG5 constructs (15 µg) encoding EBNA2 or
HA-tagged SMN, as indicated. Cells were harvested and subjected to
SDS-10% PAGE and Western blotting by using MAbs S12 (anti-LMP1), R3
(anti-EBNA2), 3F10 (anti-HA), and anti--actin MAb (Sigma). The
positions of the respective proteins are indicated by arrows. The
positions of the molecular mass markers (in kilodaltons) are indicated
on the left side. (C) Subcellular distribution of EBNA2, DP103, and
SMN. HeLa cells transfected with pSG5-HA (red signals) or pEGFP-C1
(green signals) constructs (5 µg) encoding the corresponding fusion
proteins of EBNA2, DP103, or SMN were immunostained and analyzed by
confocal laser scanning microscopy. HA-tagged proteins were visualized
by using anti-HA 3F10/anti-rat TRITC MAbs. The localizations of
coexpressed SMN and DP103 (upper panel), EBNA2 and SMN (middle panel),
or EBNA2 and DP103 (lower panel) are shown. In the merged images,
colocalization results in a yellow signal. (D) Subcellular localization
of endogenous SMN and EGFP-EBNA2 in BJAB cells. BJAB cells mock
transfected (a) or transfected with 10 µg of pEGFP-C1 EBNA2 (b, c,
and d) were immunostained by using anti-SMN 7B10/anti-mouse TRITC MAbs
and subjected to confocal laser scanning microscopy. In the merged
image (subpanel d), colocalization results in a yellow signal.
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To test whether these findings were also reflected in elevated levels
of endogenous viral LMP1 protein, Western blot analysis
of
cotransfected P3HR1 cells was performed (Fig.
2B). In P3HR1
cells
transfected with empty vector no expression of LMP1 could
be detected,
since these cells harbor an EBNA2-deleted, nontransforming
EBV genome.
Expression of EBNA2 induced LMP1 expression; coexpression
of EBNA2 and
SMN further increased the strength of the LMP1 signal,
suggesting that
coactivation of the LMP1 promoter by EBNA2 and
SMN is also relevant in
the context of latently EBV-infected B
cells. Since SMN has been
implicated in RNA processing, it is
interesting to note that in this
assay the level of EBNA2 expression
was not elevated by coexpressed
SMN. Furthermore, neither expression
of EBNA2 nor coexpression of EBNA2
and SMN increased the activity
of a pSG5 luciferase construct
(pSG5-luc) tested in three independent
experiments in BJAB cells (data
not shown). Since all expression
vectors used were pSG5 constructs
containg the simian virus 40
promoter and a
-globin intron to
facilitate protein synthesis,
these results argue against a possible
increase in luciferase
activity or LMP1 expression due to a more
efficient splicing by
the overexpression of SMN. A second control
experiment showed
that the coactivation demonstrated above was also not
due to an
increased viability of cells overexpressing SMN, since a
synergistic
antiapoptotic activity of SMN and Bcl-2 had been described
(
13).
Fluorescence-activated cell sorting (FACS) analysis
of transfected
P3HR1 cells from three independent experiments revealed
that the
relative quantity of gated, living cells did not significantly
differ, irrespective whether they overexpressed EBNA2 and/or SMN
(data
not
shown).
The direct interaction of EBNA2 and DP103 (
10) and the
functional cooperation of EBNA2 and SMN described here should be
reflected in the subcellular distribution of these proteins. Therefore,
EBNA2, DP103, and SMN were transiently coexpressed in HeLa cells
as
EGFP- or HA-tagged fusion proteins, immunostained, and subjected
to
confocal laser scanning microscopy (Fig.
2C). DP103 and SMN
were
detected dispersed in cytoplasm and distinct punctate subnuclear
structures (gems or coiled bodies) (Fig.
2C, upper panel), as
previously reported (
2). Interestingly, these structures
were
also included within the strictly nuclear distribution pattern
of
EBNA2, when SMN (Fig.
2C, middle panel) or DP103 (Fig.
2C,
lower panel)
were coexpressed with EBNA2. In contrast, unlike
its dispersed nuclear
distribution in HeLa cells, expression of
EGFP-EBNA2 in BJAB cells
resulted in a speckled nuclear pattern.
Endogenous SMN protein could be
detected by immunostaining in
cytoplasm and nuclear gems and/or coiled
bodies (Fig.
2D, subpanel
a) of mock-transfected BJAB cells. A portion
of the cells, however,
lacked the nuclear gems and/or coiled bodies or
showed a diffusely
dispersed nuclear staining (data not shown).
Furthermore, the
number of gems or coiled bodies detectable in BJAB
cells (2 to
4 per cell) was lower than in HeLa cells (6 to 16 per
cell). Strikingly,
a relocation of endogenous SMN to a speckled nuclear
pattern,
partially colocalizing with the EGFP-EBNA2 signals, could be
detected
in cells transfected with EGFP-EBNA2 (Fig.
2D, b to d). Thus,
if we take into account the limits of resolution provided by the
system
used, EBNA2 colocalizes with SMN and DP103 in HeLa cells
within the
same punctate subnuclear structures, most likely nuclear
gems and/or
coiled bodies. Furthermore, EGFP-EBNA2 expression
in BJAB cells results
in a relocation of endogenous SMN to nuclear
speckles, partially
colocalizing with EBNA2. These data suggest
that EBNA2 can target
nuclear gems or coiled bodies and, depending
on the cell type, release
SMN from these
structures.
Enhanced coactivation of the LMP1 promoter by EBNA2 and a DP103
binding-deficient SMN mutant.
The results outlined in Fig. 1
showed that coactivation by EBNA2 and SMN was slightly decreased by the
coexpression of DP103. This raised the question of whether binding to
DP103 influences the ability of SMN to functionally cooperate with
EBNA2. Therefore, several SMN mutants (depicted in Fig.
3B) were expressed in 293GP cells and
tested for their ability to coimmunoprecipitate endogenous DP103 (Fig.
3A). The deletion of both exons 6 and 7 resulted in a loss of binding,
whereas the SMA-associated deletion of exon 7 alone (SMN Ex7) or the
two patient-derived point mutations (E134K and Y272C) did not abolish
the interaction with DP103. Deletion of the first exon (SMN N27),
shown to be negative in spliceosomal assembly (7), also
did not affect binding to DP103. This mapping of the DP103 binding site
to exon 6 of SMN was confirmed by testing several deletion mutants,
including those deleting exon 7 or exons 6 and 7 in the yeast
two-hybrid system (data not shown).
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FIG. 3.
Enhanced coactivation of the LMP1 promoter by DP103
binding-deficient SMN Ex6/7. (A) Mapping of the DP103 binding site
on SMN. 293GP cells were transfected with pSG5 constructs encoding
HA-tagged SMN mutants (10 µg) as indicated. After 36 h native
cell extracts were immunoprecipitated with anti-HA MAb 3F10 (IP: anti
HA and control 2) or unspecific MAb 3A6 (controls 1 and 3) and analyzed
by SDS-10% PAGE and Western blotting. Precipitated transfected SMN
mutants were detected by using anti-HA MAb 3F10 (WB: anti HA), and
coprecipitated endogenous DP103 was detected by using anti-DP103 MAb
8H4 (WB: anti DP103). The positions of the molecular mass markers (in
kilodaltons) are indicated on the left side of each panel. Deletion of
SMN exon 6 abolished coprecipitation of endogenous DP103. (B) Schematic
representation of the SMN mutants tested. (C) Coexpression of EBNA2 and
the HA-tagged DP103 binding-deficient SMN mutant SMN Ex6/7 further
increased coactivation of the 327/+40 LMP1 promoter luciferase
construct. Assays were performed as described for Fig. 1B. Graphs
represent the mean values of three independent experiments performed in
duplicate (±SEM). (D) Immunofluorescence of HA-tagged WT SMN (a) and
SMN Ex6/7 (c) expressed in HeLa cells and stained with 3F10
anti-HA/anti-rat TRITC MAbs. (b and d) Nuclei were visualized by using
DAPI (4',6'-diamidino-2-phenylindole). Loss of binding to DP103
released SMN Ex6/7 from nuclear gems/coiled bodies. (E) Enhanced
colocalization of EBNA2 and DP103 binding-deficient SMN Ex6/7. HeLa
cells coexpressing EGFP-EBNA2 (a) and HA-tagged SMN Ex6/7 (b) were
stained by using anti-HA 3F10/anti-rat TRITC MAbs and subjected to
confocal laser scanning microscopy. In the merged image (subpanel c),
colocalization results in a yellow signal.
|
|
Indirect immunofluorescence of transfected HeLa cells further revealed
that, in contrast to WT SMN which was localized in
the cytoplasm and
nuclear gems or coiled bodies (Fig.
3D, a and
b), the DP103
binding-deficient SMN
Ex6/7 mutant was now also
detectable within
the whole nucleus. (Fig.
3D, c and d). Furthermore,
confocal laser
scanning microscopy of cotransfected HeLa cells
showed colocalization
of EBNA2 and SMN
Ex6/7 within the same
nuclear staining pattern
(Fig.
3E), indicating that the loss of
binding to DP103 releases
significant amounts of this SMN mutant
from nuclear gems or coiled
bodies. Interestingly, compared to
WT SMN, SMN
Ex6/7 had an
increased potential to coactivate the
viral LMP1 promoter in the
presence of EBNA2, as demonstrated
by luciferase assays performed in
BJAB cells (Fig.
3C). In contrast,
neither the SMN mutant negative in
spliceosomal assembly (SMN
N27) nor the SMA-associated SMN mutants
(
Ex7, E134K, and Y272C)
were able to coactivate the LMP1 promoter
above the level of WT
SMN in the presence of EBNA2 (data not shown),
suggesting that
the shown coactivation involves properties of SMN
distinct from
its function in spliceosomal
assembly.
EBNA2-mediated transactivation of the LMP1 promoter involves
binding of EBNA2 to DP103.
Our previously published data
(10) demonstrated that EBNA2 interacts with the C terminus
(aa 665 to 824) of DP103. Since it was shown here that coexpression of
EBNA2 and a DP103 binding-deficient SMN mutant resulted in an enhanced
coactivation of the LMP1 promoter, we asked where the binding site of
SMN on DP103 is located. Therefore, several HA-tagged DP103 mutants
(depicted in Fig. 4B) were expressed in
293GP cells and tested for their ability to
coimmunoprecipitate coexpressed myc-tagged SMN (Fig. 4A). Deletion of
aa 665 to 824 (C159) abolished binding to SMN, whereas mutants
deleting more central parts of DP103 (341-461 and 456-547) still
bound as efficiently as WT DP103. Note that the two mutants affecting
consensus DEAD-Box motives, DP103 341-461 deleting a putative ATP
binding site and DP103 K112N mutating a putative ATPase motive
(GK112T to GN112T),
described as essential for eIF4A activity (29), were still
able to interact with SMN. Thus, the binding sites for both SMN and
EBNA2 are located within the C terminus (aa 665 to 824) of DP103,
leading to the hypothesis that the binding of EBNA2 to the C terminus
of DP103 releases DP103-complexed SMN. To test this, luciferase assays
were performed in BJAB cells by using the 327/+40 and 154/+40 LMP1
promoter constructs (Fig. 4C). Compared to WT EBNA2, the DP103
binding-deficient mutant EBNA2 121-216 was severely impaired in
transactivating the LMP1 promoter, whereas coexpression of SMN rescued
transactivation to WT levels. This result suggests that DP103
binding-deficient EBNA2 121-216 is not able to release sufficient
amounts of endogenous SMN from its DP103-bound state and, further, that
the mechanism of EBNA targeting DP103 to release SMN is relevant for
transactivation. Surprisingly, a similar result could be obtained by
testing EBNA2 322LE (Fig. 4C), an insertion mutant shown to be unable
to bind to RBPJ (34) and therefore to be impaired in
both transactivation and transformation (5, 12).
Coexpression of SMN rescued transactivation of EBNA2 322 LE above WT
levels, indicating that targeting DP103 and binding to RBPJ are
separate mechanisms involving distinct properties of EBNA2. To further
dissect the role of RBPJ in this context, a set of mutated LMP1
promoter luciferase constructs (LL0 to LL9) (18),
schematically represented in Fig. 5A,
were examined in BJAB cells (Fig. 5B). The full-length 327/+40
promoter construct, containing two RBPJ sites and, to a lesser
extent, a truncated 232/+40 construct, containing only one
RBPJ-site, were EBNA2 responsive and coactivated by EBNA2 and SMN.
All further truncated constructs tested (199/+40 to 34/+40) were
not responsive to either EBNA2 or EBNA2 and SMN, suggesting that the
presence of RBPJ bound to its cognate promoter sequences is
essential for coactivation by EBNA2 and SMN. To further investigate
this, a luciferase reporter construct containing a 12-fold multimerized RBPJ binding-site (pGa-981-21) (37) was tested in BJAB
cells (Fig. 5C). EBNA2 transactivation could be titrated in an almost linear fashion, but coexpression of SMN did not result in an additional stimulation. Furthermore, expression of the RBPJ binding-deficient EBNA2 322LE mutant resulted in a complete loss of transactivation which, in contrast to the results obtained when testing the LMP1 promoter, could not be rescued by coexpression of SMN. These data suggest that the presence of RBPJ bound to the promoter is necessary but is not sufficient for coactivation by EBNA2 and SMN.
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FIG. 4.
EBNA2-mediated transactivation of the LMP1 promoter
involves binding of EBNA2 to DP103. (A) Mapping of the SMN binding site
on DP103. 293GP cells were transfected with pSG5 constructs encoding
HA-tagged DP103 mutants and WT myc-tagged SMN, as indicated. Cell
extracts were immunoprecipitated with anti-HA MAb 3F10 (IP: anti HA and
control 2) or irrelevant MAb 9C2 (controls 1 and 3) and analyzed by SDS-10% PAGE and
Western blotting. Precipitated HA-tagged DP103 mutants were detected by
using anti-HA MAb 3F10 (WB: anti HA), coprecipitated myc-tagged WT SMN
by using anti-myc MAb 9E10 (WB: anti myc). Panels designated input
represent ca. 10% of unprecipitated extracts. The positions of the
molecular mass markers (in kilodaltons) are indicated on the left side
of each panel. Deletion of aa 665 to 824 of DP103 (C159) abolished
coprecipitation of myc-tagged SMN. (B) Schematic representation of the
DP103 and EBNA2 mutants tested. (C) Coexpression of SMN rescued
impaired transactivation of the 327/+40 LMP1 promoter luciferase
construct by the DP103 binding-deficient mutant EBNA2 121-216 and
the RBPJ binding-deficient mutant EBNA2 322LE. Assays were performed
as described for Fig. 1B. Graphs represent the mean values of three
independent experiments performed in duplicate (±SEM).
|
|
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|
FIG. 5.
The presence of RBPJ is essential but not sufficient
for coactivation by EBNA2 and SMN. (A) Schematic map of positions 327
to +40 of the LMP1 promoter and the different luciferase constructs
tested. Shaded boxes represent the positions of cellular transcription
factor binding sites, and black boxes represent the positions RBPJ
binding sites relative to the transcription start site (arrow). (B)
Deletion mutants of the LMP1 promoter were tested for responsiveness to
EBNA2 and coexpressed HA-tagged SMN in BJAB cells, as indicated.
Deletion of the RBPJ binding sites abolished EBNA2 transactivation
and coactivation by SMN. (C) No coactivation of a multimerized RBPJ
site by SMN and increasing amounts of WT EBNA2 (1, 4, and 10 µg) or
by SMN and RBPJ binding-deficient EBNA2 322LE. (B and C) Assays were
performed as described for Fig. 1B. Graphs represent the mean values of
three independent experiments performed in duplicate (±SEM).
|
|
| |
DISCUSSION |
This study demonstrates a functional cooperation of EBNA2 and SMN
as a novel mechanism involved in EBNA2-mediated transactivation of the
viral LMP1 promoter. Initially identifying SMN as a DP103-interacting protein in the yeast two-hybrid system, we further established this
interaction in B cells (Fig. 1A) and showed that SMN can coactivate the
LMP1 promoter in the presence of EBNA2, whereas DP103 exhibited a
slightly negative influence on EBNA2-mediated transactivation (Fig.
1B). Since this coactivation by EBNA2 and SMN was detectable in
different B-cell lines in both luciferase assays and by an increased
LMP1 protein level in vivo (Fig. 2B), we assume that this effect is due
to an enhanced transcriptional activation, resulting in increased
amounts of luciferase or LMP1 transcripts, respectively. In
particular, we could exclude in control experiments possible side
effects of overexpressed SMN on splicing efficiency, levels of EBNA2
expression, and the viability of the transfected cells. To dissect the
mechanism underlying the coactivation by EBNA2 and SMN, we mapped the
binding sites of both DP103 and SMN in coimmunoprecipitation
experiments from transfected mammalian 293 GP cells and in the yeast
two-hybrid system. Thereby, we could extend the results of Charroux et
al. (2), who demonstrated that deletion of the SMN exon 7 reduced binding to DP103 (there named Gemin3), since we showed that
only deletion of both SMN exons 6 and 7 completely abolished the
interaction with DP103 (Fig. 3A), suggesting that exon 6 is the main
binding site for DP103 on SMN. Furthermore, we mapped the interacting domain of SMN on DP103 to the C terminus (aa 665 to 824) of DP103 (Fig.
4A) by testing several mutants deleting different portions of DP103. In
contrast, Charroux et al. defined the binding site (aa 456 to 547) by
showing that an in vitro-translated myc-tagged 179-aa DP103 polypeptide
(Gemin3 N368C277) bound to recombinant glutathione
S-transferase (GST)-SMN in GST pulldown
experiments, whereas two mutants with deletions of large parts of DP103
(C328 and N548) did not (2). The possible existence
of multiple interaction sites with different affinities and also the
different systems used or the varying design of the mutants tested
could account for the disparate results. Testing different SMN mutants on EBNA2-mediated transactivation, we found indeed that the loss of
binding to DP103 released SMN Ex6/7 from nuclear gems and/or coiled
bodies (Fig. 3D and E) and resulted in an enhanced coactivation (Fig.
3C). Consistent with these findings, DP103 binding-deficient EBNA2
121-216 was impaired in transactivation and could be rescued to WT
levels by coexpression of SMN (Fig. 4C). This led us to the hypothesis
that EBNA2 targets DP103 to release transcriptionally active SMN, since
both EBNA2 and SMN bind to the C terminus of DP103. Furthermore,
immunofluorescence experiments suggested that EBNA2 can target nuclear
gems or coiled bodies, thereby releasing SMN (Fig. 2C and D), since the
localization of endogenous SMN changed upon expression of EGFP-EBNA2
into a speckled pattern. A similar distribution of EBNA2 and
corepressors of RBPJ in experiments with Vero cells has been
described by Zhang et al. (44). Recently, Strasswimmer et
al. (36) reported that SMN interacts with the bovine
papillomavirus E2 transactivator, resulting in an enhanced transactivation of a viral E2-responsive promoter, although the mechanisms leading to this effect have not been further elucidated. Although similar mechanisms underlying SMN-mediated coactivation within
the RNA polymerase II transcription complex could be assumed, it should
be considered that EBNA2, in contrast to bovine papillomavirus E2,
neither directly binds to SMN nor directly binds to DNA. Furthermore, the SMA-derived SMN mutants (Y272C, E134K, and Ex7) did not show a
dominant-negative effect on transactivation of the LMP1 promoter, whereas SMN Ex7 severely impaired bovine papillomavirus E2-mediated transactivation (36). Thus far, we cannot determine where
within the promoter-bound RNA polymerase II transcription complex SMN exerts its coactivational function. Although it seems very likely that
a direct interaction of SMN with the CTD of RNA polymerase II, as
reported by Pellizzoni et al. (30), is involved, a direct binding of SMN to the promoter or DNA-bound transcription factors also
seems possible. In particular, we could show that the presence of
RBPJ bound to the promoter was essential for coactivation (Fig. 5B),
but a multimerized RBPJ binding site could not be coactivated (Fig.
5C), indicating that SMN is somehow able to bridge the interaction of
EBNA2 and RBPJ. At this point, we also cannot determine whether
EBNA2, by targeting DP103 to release SMN, otherwise changes the
composition or binding affinities of the subnuclear spliceosomal
complexes containing both proteins (3) and whether these
changes could also affect transcription. Finally, different
SMN-containing nuclear complexes, as proposed by Meister et al.
(25), could be involved in the coactivation reported here.
These complexes could determine alternative functions of SMN in either
transcriptional activation or posttranscriptional processing,
supporting the idea of a transcriptosome (8) tightly coupling both functions. Regarding EBV-induced transformation of
resting human B lymphocytes, which is closely linked to LMP1 expression, our data suggest that the proposed displacement of endogenous SMN from endogenous DP103 by EBNA2 is involved in, but not
absolutely required for, EBNA2-mediated transactivation and
transformation. It has been reported in a different context that the
deletion of aa 143 to 230 or of aa 112 to 142, encompassing the DP103
binding site on EBNA2 (aa 121 to 216), severely impaired but did not
completely abolish LMP1 transactivation and viral transformation
(5, 40).
In summary, our results suggest that transcriptionally inactive SMN is
complexed to DP103 in a pool of spliceosomal proteins, most likely
within nuclear gems and/or coiled bodies. In this scenario EBNA2, by
targeting DP103, releases a transcriptionally active form of SMN that
might interact with parts of the transcription machinery, e.g., the CTD
of RNA polymerase II (30), thereby regulating
transactivation of the viral LMP1 promoter by EBNA2.
| |
ACKNOWLEDGMENTS |
This work was supported by a grant of the Deutsche
Forschungsgemeinschaft (DFG) through Sonderforschungsbereich 399 (Projekt B1).
We thank G. Laux and U. Zimber-Strobl (GSF, Munich, Germany) for
generously providing plasmids and U. Fischer (MPI für Biochemie, Martinsried, Germany) for providing antibody 7B10. We are grateful to
A. Schmid and I. Schultz (Institut für Physiologie, Homburg, Germany) and N. Schuster and K. Krieglstein (Institut für
Anatomie, Homburg, Germany) for help with confocal microscopy and to P. Sommer (Institut Pasteur, Paris, France) for helpful discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institut
für Medizinische Mikrobiologie und Hygiene, Abteilung Virologie,
Gebäude 47, Universitätskliniken, 66421 Homburg/Saar,
Germany. Phone: 496841-1623983. Fax: 496841-1623980. E-mail:
graesser{at}med-rz.uni-saarland.de.
| |
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Journal of Virology, December 2001, p. 11781-11790, Vol. 75, No. 23
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.23.11781-11790.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
