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Previous Article | Next Article 
Journal of Virology, November 1998, p. 8485-8492, Vol. 72, No. 11
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The Epstein-Barr Virus (EBV) SM Protein Enhances Pre-mRNA
Processing of the EBV DNA Polymerase Transcript
S. Catherine Silver
Key,1,2
Tomokazu
Yoshizaki,2,3 and
Joseph S.
Pagano1,2,4,*
Department of Microbiology and
Immunology,1
Department of
Medicine,4 and
UNC Lineberger
Comprehensive Cancer Center,2 University of
North Carolina at Chapel Hill, Chapel Hill, North Carolina 27599, and
Department of Otolaryngology, School of Medicine, Kanazawa
University, Kanazawa, Ishikawa 920, Japan3
Received 2 March 1998/Accepted 29 July 1998
 |
ABSTRACT |
The Epstein-Barr virus (EBV) DNA polymerase (pol) mRNA,
which contains a noncanonical polyadenylation signal, UAUAAA,
is cleaved and polyadenylated inefficiently (S. C. S. Key and J. S. Pagano, Virology 234:147-159, 1997). We postulated
that the EBV early proteins SM and M, which appear to act
posttranscriptionally and are homologs of herpes simplex virus (HSV)
ICP27, might compensate for the inefficient processing of
pol pre-mRNA. Here we show that the SM and M proteins
interact with each other in vitro. In addition, glutathione
S-transferase-SM/M fusion proteins precipitate the heterogeneous ribonucleoprotein (hnRNP) C1 splicing protein. Further, the SM protein is coimmunoprecipitated from SM-expressing cell extracts
with an antibody to the hnRNP A1/A2 proteins, which are splicing and
nuclear shuttling proteins. Finally, the amount of processed EBV DNA
polymerase mRNA was increased three- to fourfold in a HeLa cell line
expressing SM; this increase was not due to enhanced transcription.
Thus, inefficient processing of EBV pol RNA by cellular
cleavage and polyadenylation factors appears to be compensated for and
may be regulated by the early EBV protein, SM, perhaps via RNA 3'-end
formation.
| |
INTRODUCTION |
At least two of the Epstein-Barr
virus (EBV)-associated diseases, infectious mononucleosis and oral
hairy leukoplakia, are the result of primary infection and the
cytolytic phase of replication of the virus. The primary gene whose
product is needed for viral replication is the EBV DNA
polymerase gene (pol), which is one of six early viral
genes identified as being necessary and sufficient for transient in
vitro EBV DNA replication, closely following the requirements for
herpes simplex virus (HSV) replication (6, 7). In addition,
replication is dependent on the products of three cytolytic-cycle
genes: the BZLF1 and BRLF1 open reading frames (ORFs), which are
immediate-early (IE) genes, and BSLF2/BMLF1 (SM/M), which
are early genes. Although the SM/M-encoding genes are not among
the six genes essential for viral DNA replication, there is evidence
that the SM/M proteins may indirectly facilitate replication by in some
way upregulating the expression of one or more of the replication
factors (7). However, a specific function for SM/M has not
been identified.
The 1.7- and 1.8-kb poly(A) transcripts from the BSLF2 and BMLF1 ORFs
express the SM (60-kDa) and M (50-kDa) proteins, respectively (4,
38, 48), SM results from splicing of the BSLF2 ORF immediately
upstream of BMLF1 into the M reading frame (Fig.
1). Various sizes for the SM/M proteins
have been reported, possibly due to the different EBV cell lines used
for viral induction or to posttranslational modifications
(4).
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FIG. 1.
EBV BSLF2/BMLF1 (SM/M) genes, transcripts, and protein
products. The portion of the B95-8 genome that encodes the BSLF2/BMLF1
proteins is shown below a size scale. Transcription occurs in the
leftward direction, generating two transcripts of 1.8 (SM) and 1.7 (M)
kb in length. The phosphoproteins migrate at approximately 50 and 60 kDa in SDS-PAGE. The shaded portions of SM and M are identical; the
hatched region of SM represents the extra N-terminal 41 amino acids
encoded by BSLF2.
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At first thought to be promiscuous transcriptional activators of human
immunodeficiency virus (HIV), adenovirus, and EBV promoters (21,
48), SM/M proteins were later shown to affect gene expression through a posttranscriptional mechanism (2, 4, 16, 27). However, the endogenous genes that SM/M proteins targeted were not
identified. It was surmised that the SM/M proteins might be involved in
coordinating viral DNA replication (9, 10, 32). SM/M
proteins have homologs in the alpha- and betaherpesviruses, one of
which is HSV ICP27 (IE63). This protein is multifunctional, participating in poly(A) site selection and splicing as well as viral
DNA replication (28, 33, 35, 41). Homology to SM/M is in the
carboxyl terminus of ICP27, which is required for many of its functions
(1). Additionally, the amino-terminal portions of SM/M and
ICP27 proteins are arginine rich, and this region is also important in
ICP27 function (35, 41).
The EBV DNA polymerase mRNA is apparently unique among the
herpesviruses in that it has a noncanonical poly(A) signal which results in inefficient cleavage and polyadenylation (10,
18). We therefore postulated that SM/M proteins might enhance
processing of the EBV DNA polymerase pre-mRNA and regulate the supply
of functional mRNA of this critical replication gene. Possible
mechanisms included interaction of SM/M proteins with cellular proteins
involved in pre-mRNA processing, including the heterogeneous nuclear
ribonucleoprotein (hnRNP) family (47).
We report here that SM/M proteins interact with the hnRNP
complex, probably through the hnRNP C1/C2 and hnRNP A1/A2
proteins. Using an SM-expressing HeLa cell line, we show that in
RNase protection assays, SM increases levels of pol mRNA,
presumably through enhancement of its processing.
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MATERIALS AND METHODS |
Plasmids and constructs.
The glutathione
S-transferase (GST)-SM and GST-M constructs were
generated with the use of reverse transcription-PCR to amplify the
appropriate region of EBV B95-8 cDNA and subcloned into
pBS+ (Stratagene) and pGEX2 (Promega). The first strand was
generated by using the oligo(dT) primer
5'-GGACTGAGTGACATCGA(T)17-3', containing restrict-ion
sites for SalI, XhoI, and ClaI.
Amplification was by Vent polymerase (New England Biolabs) and 5' and
3' primers directed to amplify the EBV DNA from positions 84318 (BSLF2)
or 82746 (BMLF1) to 82086 with HindIII sites
engineered into 5' primers for directional cloning.
Constructs were sequenced with a Sequenase version 2.0 kit (United
States Biochemical/Amersham). The SM KpnI fragment from
pCEP-SM (kind gift of Paul Farrell [4]) was blunt-end ligated into the EcoRV site of pcDNA3 (Invitrogen) to
generate pcSM.
pCMV-W91 was created by PCR amplification of the EBV BamHI A
pol reading frame, and the XbaI-BamHI
product was ligated into the pBS+ vector containing the
cytomegalovirus (CMV) enhancer and the BamHI-KpnI
fragment of BamHI-I of the EBV genome. Mutations were generated by use of an oligonucleotide-mediated method (Sculptor kit;
Amersham). The construct for riboprobe analysis, pBS-313RPA, was made
through PCR amplification of a 300-bp fragment encompassing the 3'
cleavage site and directionally cloned into the EcoRI and HindIII sites of the pBS vector. pCMV-W91
(22) was created through PCR amplification of the
BALF5-encoding portion of the BamHI A fragment and
subcloning the amplimer into the pBS+ vector (Stratagene).
The BamHI-KpnI fragment of BamHI-I was
then subcloned downstream of the BamHI A fragment. The CMV
IE promoter/enhancer was placed upstream of BALF5 DNA in a
PstI fragment. Linker-scanner mutations were created
essentially as described previously (18, 22). Sequenase
version 2.0 (Amersham/Life Sciences) data confirmed all constructs.
In vitro translation of SM/M proteins, generation of GST fusion
proteins, and radioactive labeling of cellular proteins.
SM/M
proteins were transcribed and translated in the presence of
[35S]methionine with a coupled method (Promega).
pBS+SM/M and pcSM constructs were linearized with
HindIII and XbaI, respectively, and
transcribed with T7 RNA polymerase.
One liter of Escherichia coli BL21(pLysS) cells expressing
the GST, GST-Z, GST-M, or GST-SM fusion proteins was grown
to a density of about 0.5 (A600)/ml and then
induced with 0.1 mM isopropyl-
-D-thiogalactopyranoside for 2 h at 37°C. Cultures were pelleted, resuspended in 10 ml of
cold phosphate-buffered saline solution (PBS), and stored at 
70°C.
Lysates were made by freezing and thawing, and fusion proteins were
then conjugated to glutathione-S Sepharose 4B (Pharmacia), washed four
times with PBS, and used to precipitate labeled cellular and in
vitro-translated proteins. Akata cells (5 × 107) were
grown in the presence of [35S]methionine (1 mCi) for
24 h, and whole-cell lysates were prepared in PBS.
GST precipitation, immunoprecipitation, and Western assays.
GST precipitation was performed as described previously (45)
except that ELB-2 buffer (0.45 M NaCl, 0.1% Nonidet P-40, 0.05 M HEPES
[pH 7.3], 0.5 mM EDTA) was used. Immunoprecipitations with monoclonal
antibodies to the hnRNP C1/C2 proteins, 4F4 and 1B12, and against hnRNP
A1/A2 proteins, 1A1, were performed as reported previously (3,
47). A polyclonal SM antibody, 
SM53 (a generous gift from Paul
Farrell), was used for Western blot analysis as described elsewhere
(4).
Cell lines.
The Akata cell line (46) was
maintained in RPMI 1640 in 10% fetal calf serum. The SM-HeLa and
pcDNA3-HeLa cell lines were generated as follows. Plasmids pcSM
(described above) and pcDNA3 were transfected into HeLa S3 cells with
Lipofectamine (Gibco-BRL). The transfectants were selected in
Dulbecco's modified Eagle's medium H (DMEM-H) containing G418 (500 µg/ml) after cultivation for 2 weeks. A single SM protein-expressing
clone was subcloned. Cells were maintained in DMEM-H with 10% serum
and G418, the concentration of which was gradually increased to 700 µg/ml over 4 weeks (addition of 50 µg/ml/week) to retain SM
expression. SM-Akata was cultivated in the same way as the Akata cell
line (4, 46). CdCl2 (10 mmol/ml of medium) was
used to induce expression of SM by exposure of the cells for 6 h.
mRNA harvesting and RNase protection assays.
Cells were
lysed, and mRNA was collected with the use of the Oligotex direct
system protocol (Qiagen). mRNA (0.5 to 1 µg) was hybridized overnight
with DNA pol 3' untranslated region (UTR) antisense probe
and glutaraldehyde phosphate dehydrogenase (GAPDH) probe (Gibco-BRL).
RNase protection assays were performed as specified by the manufacturer
(Gibco-BRL). The 313-nucleotide (nt) probe to the pol
transcript was generated by linearizing pBS-313RPA with
HindIII and transcribing with T7 RNA polymerase in the
presence of [32P]UTP. Products were separated through a
5% polyacrylamide gel containing 7 M urea and analyzed by
phosphorimagery or autoradiography.
-Gal enzyme assay.
HeLa cells (5 × 105)
were transiently transfected with Lipofectamine and 6 µg of total DNA
for 4 h in DMEM-H without serum. Then cells were incubated in
DMEM-H with 10% serum as indicated in the supplier's protocols
(Lipofectamine; Gibco-BRL). -Galactosidase (-Gal) enzyme activity
was examined by two methods. Two experimental sets were assayed with
the Luminescent -gal Genetic Reporter System II kit (Clonetech)
and analyzed on a luminometer (AutoLumat LB-953; Bertholf GmbH & Co.).
One experimental set was assayed according to specifications for the
Promega -Gal enzyme assay kit and analyzed with a spectrophotometer.
| |
RESULTS |
SM/M protein-protein interactions.
SM and M are produced
by differential splicing (Fig. 1). Therefore, potential
interactions of the SM and M proteins were tested with the use of
GST-SM and GST-M fusion proteins and in vitro-translated proteins from pBS-SM and pBS-M constructs. Both of the fusion proteins
precipitated in vitro-translated M (50-kDa) and SM (60-kDa) proteins
(Fig. 2A, lanes 2, 3, 5, and 6), whereas
GST alone did not (lanes 1 and 4). These data suggest that the SM and M
interact with each other and may be capable of other protein-protein
interactions.
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FIG. 2.
GST-SM and GST-M precipitation of SM and M in
vitro-translated proteins. GST proteins were incubated with 5 µl of
in vitro-translated proteins. Precipitated proteins were separated by
SDS-PAGE (10% gel) and exposed to X-ray film. (A) The pBS-M and pBS-SM
constructs were linearized with HindIII and then
transcribed and translated in the presence of
[35S]methionine. Lanes 1 to 3 are precipitations of the
in vitro-made M protein; lanes 4 to 6 are precipitations made with the
SM-programmed lysates. (B) Illustration of the in vitro-translated
proteins arising from the pcSM deletions at the EspI,
SacII, and XhoI restriction sites. The amino acid
(a.a.) residue immediately preceding the site of cleavage is indicated
at the end of each truncation. The hatched box corresponds to the
region encoded by BSLF2; the solid box indicates an
arginine/proline-rich region, and the shaded box represents the ICP27
homology region. Residues 185 to 192 represent a potential nuclear
export signal, and residues 260 to 274 indicate a leucine-rich region.
(C) Lanes 6 to 9, GST-SM precipitation of in vitro-translated SM
and truncated SM proteins; lane 5, GST alone; lanes 1 to 4, lighter
exposure of 5 µl of programmed lysates loaded directly.
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To define the region required for SM interactions, deletions were
generated in the pcSM construct by restriction digestion followed by in
vitro transcription-translation (Fig. 2B). The larger protein,
GST-SM, was used in precipitation assays. Equivalent amounts of in
vitro-translated proteins were added to each precipitation reaction and
are comparable to the direct loads (Fig. 2C, lanes 1 to 4). All three
of the truncated proteins were precipitated by the GST-SM fusion
protein (lanes 7 to 9), as was the full-length in vitro-translated SM
protein (lane 6). GST-SM precipitation of the in vitro-translated
SM proteins appeared significantly reduced when the
SacII-truncated protein was included in the assay (compare
lanes 6 and 7 with lane 8). The truncated protein resulting from the
XhoI deletion, which removes a putative leucine-heptad region (20), also reduced the SM/SM interaction (lane 9).
The SacII truncation data suggest that part of the
SM domain homologous to the ICP27 protein (shaded area in Fig. 2B)
may be required for SM/SM interaction. Additionally, these data
indicate that an SM/SM protein interaction domain may lie in the
XhoI-SacII segment of the BMLF1-encoding
region. Since none of the C-terminal truncations abolished SM/SM
protein interaction, the N terminus may also be involved. Additionally,
since the truncations were large, it is possible that conformational
changes reduced accessibility to the N terminus, which may be the
authentic site of self-interaction. Thus, the data indicate that SM/SM
protein interaction may occur at more than one domain but is optimal
with the intact protein.
SM/M proteins interact with components of the hnRNP complex.
Since SM/M proteins appeared capable of self-interactions, we
determined whether SM/M could interact with cellular proteins, specifically, members of the RNA splicing and 3' processing families. Initially, labeled proteins were precipitated from Akata cell lysates
with the use of the GST-M and GST-SM proteins. We detected several proteins that appeared to precipitate specifically with the
SM/M fusion proteins (Fig. 3A, lanes 4 and 5) and not with beads or GST alone or with GST-Z, another EBV
protein capable of a number of protein interactions (lanes 1 to 3). The
approximate sizes of the most prominent proteins are 40 kDa, 50 kDa
(upper band, lane 4), and 60 kDa. GST-M and GST-SM proteins
precipitated a common protein (40 kDa) as well as unique
proteins (50 and 60 kDa) (compare lanes 4 and 5). Additionally,
GST-M and GST-SM proteins specifically and reproducibly
precipitated other less prominent proteins (compare lane 3 to lanes 4 and 5), including polypeptides in the 32- to 34-kDa range. To examine
whether SM might interact with members of the RNA 3' processing family,
we tested antibodies directed to these factors. After GST-M/SM
precipitation of Akata cell lysates, proteins were separated by sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and
analyzed in Western blot assays. No interactions were detected with
antibodies against members of the general 3' processing complex,
including the 50- and 64-kDa polypeptides of the
cleavage-stimulatory factor (CSF) complex, and 100- and 160-kDa
proteins of the cleavage and polyadenylation specificity factor (CPSF)
complex, poly(A) polymerase (PAP), and poly(A) binding protein II
(PAB II) (Table 1; for a review of the processing complex, see reference 15).
(Antibodies to CSF/CPSF and PAP/PAB II were generous gifts
from W. Keller and E. Wahle). Additionally, the small nuclear
ribonucleoprotein (snRNP) U1A, which has a role in 3' processing
(25, 26) as well as splicing (24), did not
interact with the GST-SM/M proteins (Table 1) (U1A
antibody was a generous gift from C. Lutz and J. Alwine). All
antibodies used detected the appropriate proteins in lanes loaded with
Akata cell extract (data not shown). However, a member of the hnRNP
family, hnRNP C1 (a 41-kDa protein), was repeatedly precipitated with
the GST-SM/M proteins (Fig. 3B, lanes 2 and 3) and detected by
Western blot with an anti-C1/C2 antibody, 4F4 (gift from G. Dreyfuss).
The faint upper band represents the 43-kDa hnRNP C2 protein
(lanes 2 and 3); on longer exposure, the C2 protein was prominent (data
not shown).
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FIG. 3.
Precipitation of cellular proteins by GST-SM/M
fusion proteins including hnRNP C1 from Akata cell lysates. (A) Akata
cells were incubated in the presence of
[35S]methionine-cysteine (Tran35S-label; ICN)
for 24 h, harvested, and lysed. Proteins from lysates were
precipitated with GST-SM or GST-M fusion protein (lanes 4 and
5) or controls (lanes 1 to 3). Proteins were separated by SDS-PAGE
(10% gel) and visualized by autoradiography. (B) Western analysis for
the 41- and 43-kDa hnRNP C1/C2 proteins. Unlabeled proteins were
precipitated from Akata lysates with GST and GST fusion proteins.
Samples were electrophoresed, transferred to Immobilon, and analyzed
for the hnRNP C1/C2 proteins with the 4F4 monoclonal antibody (gift
from G. Dreyfuss). Lane 6 shows immunoprecipitation of hnRNP C1/C2 by
the 4F4 antibody.
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TABLE 1.
RNA processing factors that are either precipitated by
the EBV GST-SM/M fusion proteins or coimmunoprecipitated with
SM/M proteins by antisera to the processing factors
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Thereafter, we focused on SM because both SM and M proteins appeared to
interact with the hnRNP C1/C2 protein. Also, reports suggest that SM/M
proteins function equivalently and that SM protein is more abundant
than M during the early viral replicative phase (4, 16, 21,
45). Antibodies directed against members of the hnRNP
complex were used to coprecipitate the SM protein from nuclear extracts
of the SM-Akata cell line that was induced with CdCl2 (see
Materials and Methods). Proteins were separated by SDS-PAGE,
transferred, and analyzed with a polyclonal antibody directed
against SM (SM53; gift from Paul Farrell). The hnRNP C1/C2
antibody, 1B12 (gift from J. Wilusz), was unable to coprecipitate SM
protein (Fig. 4, lane 4), perhaps
because the hnRNP C1/C2 epitope was masked by the SM interaction.
However, an antibody directed against the A1/A2 (32/34-kDa) members
of the hnRNP complex, 1A1 (gift from J. Wilusz), reproducibly
precipitated SM (lane 6). Under the conditions used, the 1A1 monoclonal
antibody precipitates C1/C2 as well as A1/A2 proteins
(47). The rabbit anti-mouse immunoglobulin G bridging
antibody conjugated to protein A-Sepharose did not precipitate SM (lane
5). The antibodies precipitated their respective proteins, as
determined with the 4E4 antibody (gift of J. Wilusz) directed against
the six major hnRNP polypeptides, A1/A2, B1/B2, and C1/C2 (Fig. 4,
bottom; results are summarized in Table 1). Reciprocal
coimmunoprecipitation experiments with the SM antibody, SM53, could
not be performed because of the inability of this antibody to
immunoprecipitate (data not shown). Thus, SM clearly interacts with the
hnRNP complex; candidate proteins for specific interactions are A1/A2
and C1/C2.
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FIG. 4.
hnRNP A1/A2 antibody coimmunoprecipitates SM protein. SM
expression was induced with 10 mM CdCl2 per ml of medium
for 6 h. (Top) Proteins were precipitated from induced SM-Akata
nuclear extracts with the 1A1 monoclonal antibody (lane 6) or an
antibody against the hnRNP C1/C2 protein, 1B12 (lane 4). The
precipitates were separated through an SDS-10% polyacrylamide gel and
then transferred to Immobilon. The SM53 polyclonal antibody was used
to detect SM protein. Lane 1, in vitro-translated SM; lane 2, direct
load of 30 µg of SM-Akata nuclear extract used in the
immunoprecipitations. (Bottom) Western analysis of the same gel with
the 4E4 monoclonal antibody, which recognizes all hnRNP A and C
proteins. IgG, immunoglobulin G.
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The amount of processed EBV DNA polymerase transcript is increased
in the presence of SM protein in vivo.
Previous studies have shown
that the EBV pol pre-mRNA is inefficiently cleaved and
polyadenylated due to the presence of the variant poly(A) signal,
UAUAAA, and flanking elements (18). Since the
SM/M proteins are expressed early in the viral replicative cycle and
could enhance expression of essential replication factors, we
determined whether SM/M proteins could increase posttranscriptional processing of EBV DNA pol mRNA. To test whether the SM
protein could increase the levels of the EBV DNA pol
transcript in the absence of its promoter, a pol construct
driven by the CMV IE promoter/enhancer, pCMV-W91, was generated. Also,
the SM-HeLa cell line was created by stably transfecting HeLa cells
with a construct, pcSM, in which SM expression was placed under the
control of the CMV IE promoter, and selected by gentamicin resistance (see Materials and Methods).
After transient transfections of SM-HeLa and pcDNA3-HeLa cell
lines with pCMV-W91 containing the entire EBV DNA pol gene, including its 3' UTR or with vector DNA, mRNA was selected by using the Oligotex kit protocol (Qiagen) and analyzed for the processed
pol transcript. A 313-nt probe was used in a ribonuclease protection assay. This probe is antisense to a region of pol
mRNA spanning the poly(A) signal and cleavage/poly(A) site (Fig.
5A). After cleavage, hybridization of the
313-nt probe to the processed pol mRNA should produce a
201-nt protected product (Fig. 5A). Protected RNA of this
size was detected with the RNA from pcDNA3-HeLa when
pCMV-W91, encoding EBV DNA polymerase, was introduced (Fig. 5B, lane
3), but not with vector alone (Fig. 5B, lane 2). The level of the
201-nt product was specifically and strikingly increased in SM-HeLa
mRNA but not in the vector-transfected mRNA sample (Fig. 5B; compare
lanes 4 and 5). The amount of endogenous GAPDH transcript remained
equivalent in all pcDNA3-HeLa and SM-HeLa samples (Fig. 5B, bottom,
lanes 2 to 5). Transfection efficiency, monitored by -Gal staining,
was about 10% in both cell lines. Western blot analysis with the
polyclonal antibody against SM protein (gift from P. Farrell)
demonstrated that the cell line was expressing SM for each of four
independent transfections (inset to Fig. 5C and data not shown). A
three- to fourfold enhancement in the amount of processed
pol transcript was consistently detected in the SM-HeLa
cells (Fig. 5C). Thus, SM protein appears to enhance 3' RNA
processing of the EBV DNA polymerase mRNA, which contains an
inefficient poly(A) signal.
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FIG. 5.
Comparison of the amounts of processed EBV DNA
polymerase transcript detected in the SM-HeLa cell line and the
pcDNA3-HeLa cell line by RNase protection assays. SM-HeLa and
pcDNA3-HeLa cell lines were transiently transfected with the use of
Lipofectamine with either the pCMV-W91 or the pBS+ vector.
(A) Diagram illustrating the hybridization of the 313-nt riboprobe
generated from pBS-313wtRPA to W91 mRNA. When the RNA-RNA hybrid is
treated with RNases T and A1, a 201-nt protected fragment
results. (B) RNase protection assay of 1 µg of mRNA from pcDNA3-HeLa
(lanes 2 and 3) or SM-HeLa (lanes 4 and 5) cells transfected with
vector (V) or pCMV-W91 (pol). GAPDH (Amersham) protected bands are
shown at the bottom. This experiment was repeated four times. (C)
Average fold increase, calculated from four experiments as the ratio of
the counts per minute of the protected mRNA products of pol
to GAPDH from SM-HeLa cells divided by the same ratio as detected with
pcDNA3-HeLa cell mRNA. The inset is an SM53 Western blot of
pcDNA-HeLa and SM-HeLa cell extracts.
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Although it seemed likely that the increased pol mRNA levels
were the result of a posttranscriptional mechanism, earlier reports claimed that SM/M activates heterologous viral promoters
(17, 21, 48). Later reports concluded that SM/M works
through a posttranscriptional mechanism but did not completely exclude
the possibility of an effect on transcription (4, 16, 27). Thus, we tested whether SM affected the CMV IE promoter/enhancer to increase pol transcription. CMVgal and the
promoterless BASICgal constructs (Clontech) were used in transient
pcSM cotransfection assays in HeLa or C33 cells, since they are
efficiently transfected. The -Gal constructs contain the simian
virus 40 (SV40) poly(A) signal (AAUAAA), which is more
efficient than the EBV DNA poly(A) signal (UAUAAA).
Expression of BMLF1 was reported not to affect the activity
of a -Gal reporter that contained the SV40 signal (27).
Cells were transfected and harvested 48 h later. Lysates were
prepared and assayed for -Gal activity with chemiluminescent reagents and a luminometer (AutoLumat LB-953; Bertholf GmbH & Co.)
or by a spectrophotometric method (Promega). The results of three
sets of triplicate transfections indicate a slight but insignificant increase in -Gal activity in the presence of pcSM compared with its vector background, pcDNA3 (Table
2). A fourth set of triplicate -Gal
assays was performed with the stable cell lines SM-HeLa and
pcDNA3-HeLa. Again, -Gal activity was unaffected by the presence of
SM (data not shown). Thus, there was little if any effect of SM on the
CMV IE promoter/enhancer. The data support the hypothesis that SM
increases pol mRNA levels by affecting processing of
pre-mRNA.
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DISCUSSION |
Pre-mRNA of the EBV DNA polymerase gene is cleaved and
polyadenylated inefficiently in vitro because of a noncanonical poly(A) signal (18). In this report, we show that the abundance of
processed pol mRNA is increased in vivo in cells expressing
the EBV SM early protein. In the absence of SM, which, like its homolog
the HSV ICP27 protein, acts posttranscriptionally, little mRNA can be detected. Thus, SM protein appears to compensate for the deficient processing of EBV pol RNA. Based on previous in vitro
results, SM most likely affects the cleavage/polyadenylation step in
processing of the RNA (18). However, the possibility
that SM enhances nuclear export or increases mRNA stability has not
been excluded. Effects of these mechanisms are difficult to distinguish
since all result in higher levels of processed mRNA in the cytoplasm
and indeed may not be mutually exclusive (12, 19). In any
case, what is normally a cellular process, namely,
cleavage/polyadenylation and export of mRNA from the nucleus, is
clearly facilitated by a viral protein, SM. Although the functions of
HSV ICP27 have some resemblance (4, 28, 33), SM's effects
are distinctive in that the EBV protein produces a three- to fourfold
enhancement in the level of the early mRNA, pol, for which
levels are otherwise low.
At least 11 polypeptides orchestrate the cleavage and
polyadenylation of pre-mRNA, including four members of the CPSF
complex, three members of the CSF complex, poly(A) PAP, cleavage
factors I and II, and PAB II (for a review, see reference
15). So far, interaction of SM has not been detected
with any of the six proteins that we tested. Although hnRNPs are
not known to participate in cleavage and polyadenylation, hnRNP
C1 binds to the same downstream U-rich element recognized by the 64-kDa
member of the CSF complex (47). In this work, we implicate
hnRNP C1/C2 and hnRNP A1/A2 in the pre-mRNA 3' processing of the
intronless pol transcript indirectly by showing that these
proteins interact with SM.
The hnRNP family in eukaryotes includes more than 20 proteins,
designated A through U, that are localized to the nucleus
(5). The core hnRNP complex is composed of six highly
related proteins, hnRNP A1/A2, hnRNP C1/C2, and hnRNP B1/B2
(3). hnRNP family members bind RNA through two copies
of an amino-terminal RNP motif, an RNA-binding domain, and a
carboxyl-terminal glycine-rich domain (44). Various members
of this complex have been implicated in pre-mRNA/mRNA
processing events, including splicing and nuclear shuttling
(30). In particular, recent studies of A1 indicate a
specific role in mRNA nuclear export (31, 34).
Interestingly, SM/M proteins contain an extensive leucine-rich domain
(SM coordinates 185 to 274), which includes a putative nuclear export
signal, LPSPLASLTL, similar to that of Rev/Rex required for rapid
nuclear export of retroviral RNAs (reviewed in references
11 and 19). One report suggests
that in order for Rev to transport an HIV RNA rapidly, the
polyadenylation machinery must interact with that RNA (14).
Perhaps SM/M-hnRNP complexes favor rapid export of EBV transcripts.
However, the definitive role(s) of each hnRNP member is unclear.
Thus, it is difficult to assign a particular role to SM/M-hnRNP
interaction complexes other than their involvement in pre-mRNA
processing events.
Little is known about pre-mRNA processing of EBV transcripts and
the role of SM/M proteins. The SM/M proteins, assuming that they
function to enhance 3' processing of pre-mRNA, may first form self- and
non-self-interactions through several domains, including a putative
leucine zipper domain. Second, the data obtained so far suggest that
SM/M proteins may enhance 3' processing of pol pre-mRNA by
directly interacting with members of the pre-mRNA processing complex,
namely, hnRNP C1/C2 and/or hnRNP A1/A2. Recent reports implicate
coordination of splicing with 3' processing, with splicing
factors playing an essential role in regulation of RNA 3'-end
formation. For example, the snRNP U1A interacts with PAP to
inhibit 3' processing of its own transcript (13) but
contacts the 160-kDa member of the CPSF complex to enhance processing of the late SV40 mRNA (26). However, the EBV
DNA polymerase pre-mRNA does not contain an intron. It is not spliced and is inefficiently cleaved and polyadenylated (10, 18). Thus, in this case SM/M may interact with splicing factors,
sequestering the splicing machinery and perhaps favoring the processing
of an intronless viral transcript. Indeed, there is precedence for such
a scenario, as SM/M's HSV counterpart, ICP27, appears to increase the
production of viral transcripts that are intronless and/or are
inefficiently cleaved and polyadenylated (25, 29, 33, 42).
Recent evidence suggests that the M protein may suppress the use of
cryptic 5' splice sites (43a).
ICP27 appears to have multiple functions. HSV DNA replication requires
the IE protein ICP27 (35). Interestingly, expression of the
HSV ICP27 gene can substitute for M in an in vitro EBV ori-Lyt
replication assay (7), suggesting a functional equivalence. Additionally, ICP27 is required for shutoff of host cellular protein synthesis, most probably by redistributing the snRNP and the SC35 splicing factors during infection (40, 41). ICP27 is
coimmunoprecipitated with snRNPs by the SM-specific antibody, which
recognizes the shared epitope of the snRNP family, suggesting that
redistribution of splicing proteins by ICP27 expression is carried out
through direct interaction (40). Recently, the HSV protein
has been shown to bind directly to several cellular 3' UTRs, apparently stabilizing labile transcripts (1). Homology of SM/M and
ICP27 proteins lies in the C-terminal region and includes the zinc
knuckle RNA-binding domain of ICP27 (1). In preliminary
experiments, the GST-SM/M proteins bound to the EBV pol
transcript but not to an HIV transcript containing the Rev-responsive
element (data not shown). ICP27 may also facilitate the preferential
nuclear export of HSV mRNAs transcribed from intronless genes
(33). Most notably, expression of ICP27 appears to be an
essential step in the switch from early to late viral gene expression,
and the event seems to involve increased processing of transcripts with weak polyadenylation signals (28, 29, 39, 42).
EBV DNA pol contains a functional but inefficient poly(A)
signal, UAUAAA (10, 18). Two other viruses,
figwort mosaic virus and hepatitis B virus, also contain the
UAUAAA poly(A) signal. The figwort mosaic virus P6 protein
and the hepatitis B virus precore protein are in some way involved in
regulating whether replication or pre-mRNA processing is favored
(19, 36, 37, 43). Recent evidence suggests that SM
suppresses levels of polyadenylated mRNA from intron-containing genes
but increases mRNA levels from intronless genes (37a).
Whether SM/M enhances the amount of EBV DNA pol mRNA through
a mechanism of pre-mRNA processing, nuclear exportation, RNA
stabilization, or a combination of these events remains to be
elucidated. This report provides evidence that the level of at least
one EBV transcript increases strikingly in the presence of SM/M
proteins.
What is the functional significance of SM's effect on processing
of the EBV DNA polymerase mRNA? The products of the BZLF1 (Z), BRLF1
(R), and BMLF1/BSLF2 (SM/M) genes are used in the cytolytic cycle
for viral replication (7). Z and R are IE gene products that
activate early EBV genes (8, 23), whereas SM/M is an early
gene product with a quite different level of action (4, 16,
27). In addition to regulating expression of viral genes through activating transcription, EBV may be able to regulate gene
expression at a later stage of the process. The virus may also
coordinate the timely expression of its DNA polymerase by enlisting
SM/M proteins to enhance the otherwise inefficient processing of the
mRNA of this key gene.
| |
ACKNOWLEDGMENTS |
The first two authors contributed equally to this work.
This work was supported in part by the National Cancer Institute (NIH
grant P01 CA 19014) and by a grant-in-aid from the Ministry of
Education, Science and Culture of Japan (T.Y.).
We thank Gideon Dreyfuss, Clinton MacDonald, Jeffrey Wilusz, Carol
Lutz, James Alwine, Elmar Wahle, Andreas Jenny, and Walter Keller for
generously providing antibodies directed against pre-mRNA processing
proteins. We are grateful to Paul Farrell for providing the SM53
antibody and constructs. We thank William Marzluff and Nancy Raab-Traub
for advice. We thank Maureen Caldwell and Cyd Johnson for help in
preparing the manuscript and Chunnan Liu and Luwen Zhang for
assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Lineberger
Comprehensive Cancer Center, The University of North Carolina at Chapel Hill, UNC Lineberger Comprehensive Cancer Center, Chapel Hill, NC
27599. Phone: (919) 966-3036. Fax: (919) 966-3015. E-mail: mcaldwel{at}med.unc.edu.
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Abstract
Introduction
