Previous Article | Next Article 
J Virol, January 1998, p. 236-244, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Transcription Factor Sp1 Mediates Cell-Specific
trans-Activation of the Human Cytomegalovirus DNA Polymerase
Gene Promoter by Immediate-Early Protein IE86 in Glioblastoma
U373MG Cells
Jun
Wu,*
Joseph
O'Neill, and
Miguel S.
Barbosa
Signal Pharmaceuticals, Inc., San Diego,
California
Received 17 July 1997/Accepted 1 October 1997
 |
ABSTRACT |
Human cytomegalovirus (HCMV) gene expression is highly cell and
tissue specific. Cell factor-mediated regulatory interactions are
involved in regulating the restricted expression of the HCMV major
immediate-early (IE) gene (J. F. Baskar, P. P. Smith, G. Nilaver, R. A. Jupp, S. Hoffmann, N. J. Peffer, D. J. Tenney, A. M. Colberg-Poley, P. Ghazal, and J. A. Nelson,
70:3207-3213, 1996). To gain an understanding of HCMV early gene
activation, we studied the effect of each of the three major IE
proteins, IE72, IE86, and IE55, on the HCMV DNA polymerase gene
(pol; UL54) promoter. In transient-expression assays, the
IE86 protein alone was able to transactivate the pol
promoter, but IE72 and IE55 were not, in permissive U373MG cells.
However, we were unable to detect IE86-mediated transactivation in
nonpermissive HeLa or C33-A cells. Using electrophoretic mobility shift
assays (EMSAs), we found that expression of the IE86 protein in U373MG
cells resulted in specific binding of a DNA complex to an
inverted-repeat element, IR1, of the pol promoter. Antibody
supershifting and EMSA-Western blotting experiments further showed that
IE86 and the cellular transcription factor Sp1 were components of the
IR1 DNA-binding complex. Furthermore, we found that binding of DNA by
Sp1 was dramatically increased in the presence of IE86. Interestingly, this IE86-induced DNA-binding activity of Sp1 was inhibited by a
repressor activity presented in HeLa cells. In summary, our study
suggests that a viral regulatory protein can modulate the DNA binding
activity of a cellular transcription factor, resulting in cell-specific
transactivation of viral genes.
| |
INTRODUCTION |
Human cytomegalovirus (HCMV) is a
ubiquitous member of the herpesvirus family and a medically important
pathogen that typically causes asymptomatic infections in healthy
individuals and severe complicating infections in utero as well as in
immunocompromised and immunosuppressed patients (12, 21, 34, 36,
41, 46). HCMV infection of permissive cells in culture leads to
an ordered sequential expression of viral genes which are divided into
three kinetic classes: immediate-early (IE), early, and late (7, 8, 35, 58). The IE genes are expressed upon entry of the viral
genome into the nucleus of an infected cell, and their expression requires specific cis-acting elements in the viral promoters
as well as cellular and viral trans-acting factors. The IE
genes have been extensively studied, and their expression is thought to
be essential for viral replication (22, 28, 48-51, 53-55, 60,
61). The most important of the IE gene products are the 72-kDa
IE1 (IE72; ppUL123) and the 86-kDa IE2 (IE86; ppUL122a) polypeptides
that originate from the major IE gene region of HCMV and are
transcribed under the control of a complex enhancer-promoter (3,
16, 40, 51, 56).
Early genes are expressed in a complex manner. Three subclasses of
early genes have been defined (45, 48). Transcription of
early genes is weak in the absence of the IE proteins. However, upon
synthesis of IE viral proteins, some early genes are strongly activated
(5, 33, 45, 59, 62). It has been demonstrated that IE86
alone strongly activates the UL4 and UL112-113 early genes in
transiently transfected cells (5, 27, 42) while the IE72
protein can act synergistically with IE86 to activate these genes
(5, 25, 45, 47, 62). The IE86 protein has been shown to bind
to the cis-acting negative regulatory element on the UL4
promoter and negate its repressive effect (18).
Transactivation of the UL112 gene is mediated through an interaction
between IE86 and the cellular transcription factor CREB (1, 29,
30). An expression construct encoding the major IE proteins,
IE72, IE86, and IE55, was shown to transactivate the
pol promoter in the fully HCMV-permissive cells known
as human foreskin fibroblasts (HFF) (24). This
activation was mediated by a cis element, IR1, present
in the pol promoter (24). However, no IE86
binding sequences had been identified in this promoter. Recently, it
was shown that cellular transcription factors, such as ATF and Sp1, are
involved in transactivation of the pol promoter (26,
32). HCMV infection upregulates the expression of genes
encoding the cellular transcription factors NF-
B and Sp1 in human
embryonic lung (HEL) fibroblasts (63, 64). Overall, these
data suggest that the mechanism by which IE86 activates
transcription of HCMV early genes seems to involve protein-DNA and
multiple protein-protein interactions, i.e., interactions with
upstream bound cellular transcription factors and with the basal
transcription complex (14, 31, 43). Since the HCMV gene
expression cascade is cell type restricted, it is possible that
modulation of transcription by HCMV regulatory proteins and/or
cell-specific transcription factors may determine the permissiveness of
this gene expression cascade.
We were interested in understanding HCMV temporal gene regulation,
especially the mechanism by which IE proteins mediate early gene
activation, and in identifying cellular transcription factors involved
in the DNA binding activity of IR1. Toward this goal, we studied the
effect of each of the three major IE proteins on UL54 (pol)
early gene promoter activity. Our results indicate that only IE86 alone
is able to transactivate the UL54 (pol) promoter in
permissive U373MG cells. Expression of IE86 resulted in the formation
of a specific DNA complex on a cis element, IR1, of the
pol promoter (24). To elucidate the IR1-bound
proteins, we found that the IE86 protein and the cellular transcription factor Sp1 were components of the IR1-DNA complex. In addition, we
found that binding of DNA by Sp1 was dramatically increased in the
presence of IE86 in U373MG cells. However, this enhanced DNA binding by
Sp1 was present only in the permissive U373MG cell line, not in
nonpermissive HeLa cells. In contrast, this IE86-mediated binding of
DNA by Sp1 was inhibited by a repressor activity present in HeLa cells.
In summary, these data demonstrate that the cellular transcription
factor Sp1 is involved in the DNA-binding activity of IR1 of the
pol promoter. Furthermore, we demonstrate that a repressor
activity present in HeLa cells somehow inhibits this IE86-induced IR1
DNA binding.
| |
MATERIALS AND METHODS |
Plasmid construction.
The UL54 (pol) promoter
sequence from positions 
425 to +15 and the UL112 promoter sequence
from positions 352 to +37 were amplified by PCR with cosmid pCM1058
(a gift from Peter Ghazal) as a template. The sequences of the
oligonucleotide primers used for amplification of the UL54 promoter
were 5'-CCCAAGCTTGGGGGAATTCAACTCGTACAAGCAG-3' (forward
primer) and 5'-CCCAAGCTTGGGTCAGACGACGGTGGTCCC-3' (reverse primer). These primers introduced HindIII restriction
sites at the 5' and 3' ends of the UL54 (pol) promoter
fragment, allowing insertion of this fragment into the pGL2-basic
luciferase reporter plasmid (38) (Promega). The sequences of
the oligonucleotide primers used for the amplification of the UL112
promoter were 5'-CGGGGTACCCCGCACAGAGGTAACAAC-3' (forward
primer) and 5'-GAAGATCTTCGGCGGTGGAGCGAGTGC-3' (reverse
primer). These primers introduced a KpnI and a
BglII restriction site at the 5' and 3' ends of the UL112
promoter fragment, respectively, allowing directional insertion into
the pGL2-basic luciferase reporter plasmid (38) (Promega).
The PCR fidelity of the UL54 (pol) and UL112 promoter
sequences was confirmed by sequencing. Expression vectors for each of
the HCMV IE proteins
RSVIE72, RSVIE86, RSVIE55 (all gifts from Peter
Ghazal), and pSVH, which expresses all three IE proteins from the major
IE gene region (kindly provided by Richard M. Stenberg)have been
described previously (9, 24).
Transfection and infection assays.
U373MG, HFF, HeLa, and
C33-A cells were cotransfected with the reporter construct and the
indicated effector by use of the Profection mammalian transfection
system (Promega). Forty hours posttransfection, cells were harvested
and assayed for luciferase activity as described by the manufacturer
(Analytical Luminescence Laboratory).
Establishment of stable U373MG and HeLa cell lines expressing
IE86.
The RSVIE86 and pSV2Neo (Clontech Laboratories, Inc.)
selection plasmids were cotransfected into U373MG and HeLa cells by the
calcium phosphate method. Transfectants were selected in medium containing 0.6 mg of G418 per ml on the third day after transfection. G418-resistant clones were expanded, and 3 × 104
cells were seeded in triplicate in a 96-well plate. Cells were harvested and assayed for IE86 by Western blot analysis. Clones showing
expression of IE86 protein were amplified and used for further studies.
Western blot analysis.
For each sample, 25 µg of total
protein was separated by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (PAGE) and transferred to a Hybond-ECL nitrocellulose
membrane (Amersham). A monoclonal antibody specific for the HCMV IE
proteins (MAB 810; Chemicon) was used. Proteins bound by primary
antibodies were detected with an alkaline phosphatase-conjugated
secondary antibody in accordance with the manufacturer's protocol
(Amersham).
Preparation of nuclear extracts.
U373MG, U373-IE86, HeLa,
and HeLa-IE86 nuclear extracts were prepared in accordance with the
protocol described by Dignam and coworkers (11).
EMSAs.
The sequences of the IR1 probes were
5'-GTTACAGGCTCCGCCTTC (forward) and
5'-GGAAGGCGGAGCCTGTA (reverse). The sequences of the IRmut
probes were 5'-GTTACAGATATCGCCTTC (forward) and
5'-GGAAGGCGATATCTGTA (reverse) (underlined
nucleotides are mutated). The sequences of the CRS probes were
5'-CGTTTAGTGAACCGTCAGAT (forward) and
5'-TCTGACGGTTCACTAAACG (reverse). The sequences of the
CRSmut probes were 5'-GCGGCGGTGAACCGTCAGAT (forward) and
5'-TCTGACGGTTCACCGCCGC (reverse). The sequences of the EAIE2
probes were 5'-TAGCGTTGCGATTTGCAGTCCGCTCC (forward) and
5'-GGAGCGGACTGCAAATCGCAACGCT (reverse). The sequences of the EAIE2mut probes were 5'-TAGCGTTGTAACCCATAGTCCGCTCC (forward)
and 5'-GGAGCGGACTATGGGTTACAACGCT (reverse). Sp1 and CREB
consensus oligonucleotides were purchased from Promega. The probes and
competitors were produced by annealing the appropriate oligonucleotides
as described by Kerry and coworkers (24). For use as probes,
the IR1 oligonucleotide was end labeled with
[
-32P]dATP and the Sp1 oligonucleotide was labeled
with [
-32P]ATP. Five-microgram quantities of nuclear
extracts were incubated with 1 µg of poly(dI-dC) · poly(dI-dC)
and 10,000 cpm of labeled oligonucleotide for 30 min at room
temperature in binding buffer (75 mM NaCl, 15 mM Tris [pH 7.5], 1.5 mM EDTA, 1.5 mM dithiothreitol, 7.5% glycerol, 0.3% Nonidet P-40, 20 µg of bovine serum albumin per ml). A 4% polyacrylamide gel was
prerun in standard 0.25× Tris-borate-EDTA at 150 V for 1.5 h.
Sample reactions were then subjected to PAGE. The gels were dried and
subjected to autoradiography. In competition and antibody supershift
experiments, a 50-fold excess of unlabeled oligonucleotides or 1 µg
of monoclonal antibody specific for IE proteins (MAB 810, as described
above) and polyclonal antibodies specific for NF-B p65, NF-B p50,
Sp1, ATF, and CREB (Santa Cruz Biotechnology) were used, respectively.
For electrophoretic mobility shift assays (EMSAs) and Western blotting
experiments, after PAGE electrophoresis, the sample was transferred to
DEAE and nitrocellulose membranes in regular Western Tris-glycine
buffer. Recombinant IE86 protein (kindly provided by Peter Ghazal) was used as a control.
| |
RESULTS |
IE86 protein transactivates the pol promoter in
permissive U373MG cells.
To gain an understanding of the mechanism
by which IE86 transactivates the HCMV pol promoter, we first
determined whether the 425/+15 pol (24)
promoter construct responded to IE proteins in the U373MG cells.
Indeed, we found that cotransfection with pSVH, a plasmid expressing
the genes encoding three IE proteins, IE72, IE86, and IE55, from the
endogenous genomic fragment under the control of their own major IE
promoter (9), resulted in up to a 160-fold activation of the
pol promoter, as measured by expression of the luciferase
reporter (data not shown). This result is consistent with those
reported for HFF (9, 51, 52). Thus, we were assured that the
pol-luciferase reporter construct carried all regulatory
elements previously shown to mediate the response to the IE proteins
expressed from the pSVH expression vector (9, 48, 52).
However, it remained unclear which of the three IE proteins play a
major role in promoter activity. Therefore, we transfected expression
constructs encoding the IE72, IE86, and IE55 cDNA sequences under the
control of the heterologous Rous sarcoma virus (RSV) promoter. We found
that the IE86 expression vector alone was capable of activating the
pol promoter significantly (40- to 55-fold) (Fig.
1). Neither the IE72 nor the IE55
expression vector yielded significant activation (Fig. 1). Western blot
analysis showed that pSVH expressed about 3- to 4-fold more IE86
protein than the RSVIE86 vector (data not shown), thus suggesting that the difference between pSVH (160-fold) and RSVIE86 (40- to 55-fold) activation of the pol promoter is likely due to higher
levels of the IE86 protein. We conclude that among the IE gene
products, the IE86 protein plays a major role in the transactivation of the pol promoter in permissive U373MG cells.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 1.
The IE86 protein is essential for the activation of the
HCMV DNA polymerase (pol) gene promoter. U373MG cells were
cotransfected with the pol-luciferase reporter and
increasing amounts of the IE gene expression vectors RSVIE86, RSVIE72,
and RSVIE55 and a  -galactosidase control vector. Luciferase activity
was normalized to -galactosidase activity. The data represent the
results of three independent experiments.
|
|
Cell type-specific transactivation of the pol promoter
by IE86.
HCMV has a very restrictive species and cell tropism. The
molecular events allowing the virus to productively infect some cell
types but not others has not been investigated extensively. It has been
shown that the HCMV gene products can act individually or in
combination to regulate the expression of viral and cellular promoters
in a manner that is dependent on the promoter, the host cell, and the
IE gene products present (6). We were interested in
determining if early gene promoters, in particular the pol promoter, were expressed in a cell type-specific fashion. Toward this
goal, we analyzed the response of two early gene promoters, pol and UL112, to IE86 expression in permissive and
nonpermissive cells. In permissive glioblastoma U373MG and HFF, the
pol promoter was transactivated by IE86 60- and 35-fold,
respectively (Fig. 2A and B) while the
UL112 promoter was transactivated by IE86 28- and 18-fold, respectively
(Fig. 3A and B).
View larger version (31K):
[in this window]
[in a new window]
|
FIG. 2.
Transactivation of the pol promoter by IE86
in the permissive U373MG and primary HFF cells. The
pol-luciferase (pol-luc) and -galactosidase reporters
were cotransfected with increasing amounts of the RSVIE86 expression
vector in permissive U373MG (A) and HFF (B) cells and in nonpermissive
HeLa (C) and C33-A (D) cells as indicated. Luciferase activities were
normalized to -galactosidase activity. Units are fold activation.
The data represent the results of three independent experiments.
|
|
View larger version (35K):
[in this window]
[in a new window]
|
FIG. 3.
Transactivation of the UL112 promoter by IE86. The
UL112-luciferase (UL112-luc) and -galactosidase reporters were
cotransfected with increasing amounts of the RSVIE86 expression vector
in permissive U373MG (A) and HFF (B) cells and in nonpermissive HeLa
(C) and C33-A (D) cells as indicated. Luciferase activities were
normalized to -galactosidase activity. Units are fold activation.
The data represent the results of three independent experiments.
|
|
Interestingly, we were unable to detect IE86-mediated transactivation
of the
pol promoter in nonpermissive HeLa or C33-A
epithelial
cells (Fig.
2C and D). In contrast, the UL112 reporter was
efficiently
transactivated by cotransfection with the IE86-expressing
vector
in both HeLa and C33-A cells (Fig.
3C and D). The data shown are
normalized for
-galactosidase levels expressed from a cotransfected
control plasmid. Therefore, the lack of luciferase expression
from the
pol-luciferase reporter is not simply due to inefficient
transfection. More importantly, the UL112-luciferase reporter
was still
activated by IE86 in those cells, which is consistent
with the findings
of Colberg-Poley and coworkers (
6). pSVH,
which coexpresses
IE1 (IE72) and IE2 (IE86 and IE55), activates
the
pol
promoter in U373MG cells (160-fold). In contrast, pSVH
transactivates
the
pol promoter in HeLa cells by seven- to ninefold
(data
not shown). The 20-fold difference between the transactivation
activities in permissive U373MG and nonpermissive HeLa cells may
be a
means of identifying the events required for IE86-mediated
induction of
pol promoter transcription.
To ascertain that the difference between the responses of the
pol promoter to IE86 in glial and in epithelial cells was
not
due to differences in expression levels, we tested the same
reporter
plasmids in cell lines stably expressing the IE86 protein.
Several
U373MG and HeLa cell clones constitutively expressing similar
amounts of IE86 were transfected with increasing amounts of the
pol-luciferase and UL112-luciferase reporters, respectively.
The
data representing three different stable clones showed that the
luciferase gene driven by the
pol promoter was activated in
U373-IE86
cells but not in HeLa-IE86 cells (Fig.
4A and B) while the luciferase
gene
driven by UL112 promoter showed significant activation in
both
U373-IE86 and HeLa-IE86 cells (Fig.
5A
and B). Western blot
analysis showed that equal amounts of IE86 protein
were expressed
from the reporter-transfected stable cells (Fig.
4C and
D; Fig.
5C and D). Therefore, we concluded that IE86 may transactivate
the
pol promoter in a cell type-specific manner.
View larger version (23K):
[in this window]
[in a new window]
|
FIG. 4.
Activation of the pol promoter in the U373MG
stable cell line expressing IE86. The U373MG parental line and
U373-IE86 stable cell line (A) or the HeLa parental line and HeLa-IE86
stable cell line (B) were transfected with increasing amounts of the
pol-luciferase (pol-luc) reporter. Cells were harvested, and
luciferase activity was assayed. The levels of expression of IE86
protein in the stable cell lines (C and D) were determined by Western
blotting with a monoclonal antibody specific for the HCMV IE
proteins.
|
|
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 5.
Activation of the UL112 promoter in U373-IE86 and
HeLa-IE86 stable cell lines. The U373MG parental cell line and
U373-IE86 stable cell line (A) or the HeLa parental line and HeLa-IE86
stable cell line (B) were transfected with increasing amounts of the
UL112-luciferase (UL112-luc) reporter. Cells were harvested, and
luciferase activity was assayed. The levels of expression of IE86
protein in the stable cell lines (C and D) were determined by Western
blotting with a monoclonal antibody specific for the HCMV IE
proteins.
|
|
Identification of a cell-specific DNA-binding activity specific for
the inverted-repeat element IR1.
An inverted-repeat element, IR1,
has been shown to mediate activation of the pol promoter by
the HCMV IE proteins expressed from the pSVH vector. The cellular
factors present in uninfected HFF cells bind to this IR1 element, and
its binding increases with time upon viral infection (24).
To determine whether IR1 binding was also present in U373MG cells and
whether the IE86 protein was present in the IR1 DNA-binding complex, we
conducted EMSAs with radioactively labeled IR1 oligonucleotides
(24) and nuclear extracts from parental as well as
IE86-expressing U373MG and HeLa cells. Interestingly, we found that a
specific protein-DNA complex was present in the three different
IE86-expressing U373MG cell clones but not in extracts from the
parental cells (Fig. 6A). In contrast,
HeLa cells did not show a unique complex in the presence of IE86
protein (Fig. 6B). The absence of the IE86-specific complex in HeLa
cells is not due to a lack or lower level of IE86 protein since, as
shown in Fig. 4C and D and 5C and D, the protein is expressed at
similar levels in U373MG cells.
View larger version (56K):
[in this window]
[in a new window]
|
FIG. 6.
Identification of an IR1-specific DNA-binding complex in
U373MG cells expressing IE86. Five-microgram quantities of nuclear
extract from U373MG and U373-IE86 (A) or HeLa and HeLa-IE86 (B) cell
lines were incubated with 32P-labeled IR1 oligonucleotide.
IR1 binding was analyzed by EMSA. (C) U373MG-IE86 nuclear extract was
incubated with labeled IR1 oligonucleotide and a 50-fold excess of
either unlabeled wild-type (IRwt) or mutant (IRmut) IR1
oligonucleotides. The arrows indicate the specific complex. NS,
nonspecific complexes.
|
|
To address whether the protein complex seen in IE86-expressing U373MG
cell extracts was specific for the IR1 element, we conducted
a
competition experiment. As indicated in Fig.
6C, the wild-type
IR1
oligonucleotide (at a 50-fold excess) was able to block the
formation
of the DNA-protein complex in the IE86-expressing U373MG
nuclear
extracts, but the same amount of this oligonucleotide
carrying a
mutation in the IR1 sequence was not. Therefore, we
conclude that the
unique complex is specific for the IR1 element.
The data indicated that
there was no specific IR1 binding in U373MG
cells. However, expression
of the IE86 protein in U373MG cells
induced an IR1-specific DNA binding
activity on the
pol promoter.
IE86 protein is present in the IR1 DNA-binding complex.
Since
expression of IE86 protein in U373MG cells leads to IR1-specific DNA
binding, we investigated whether the IE86 protein was present in the
IR1 complex. To address this question, we performed antibody supershift
experiments using an IE86-specific monoclonal antibody. As shown in
Fig. 7A, addition of a monoclonal
antibody that recognizes IE86 (MAb 810) disrupted the IR1-specific
complex. In contrast, two other antibodies specific for two subunits of the cellular transcription factor NF-B (p65Ab and p50Ab) had no
effect on the IR1 complex. Titration of the IE86 antibody showed that
the effect was specific for the IR1 complex (data not shown). To verify
that IE86 is present in the IR1 DNA-binding complex, we conducted
EMSA-Western blot analysis. As shown in Fig. 7B, the shifted IR1 probe
was efficiently transferred onto a DEAE membrane (lane 2). The proteins
present in the IR1 complex were transferred to a nitrocellulose
membrane and then analyzed by Western blotting with the IE86-specific
antibody (Fig. 7C and D, lanes 2). However, this antibody did not show
a band in lanes containing U373-IE86 cell lysate or bacteria if the IR1
probe was not added (Fig. 7D, lanes 3 and 4), suggesting that the band recognized by the IE86-specific antibody represents the IE86 protein present in the IR1 DNA-protein complex but not free IE86 protein. Therefore, we concluded that IE86 is part of the IR1 DNA-binding complex.
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 7.
IE86 antibody recognizes the IR1-DNA complex-bound IE86
protein. (A) U373-IE86 nuclear extract was incubated with labeled IR1
oligonucleotide and either a monoclonal antibody specific for the HCMV
IE proteins (MAb 810) or polyclonal antibodies specific for NF-B p65
and p50 subunits (p65 Ab and p50 Ab, respectively). U373-IE86 with the
IR1 probe was used as a control. (B to D) EMSA was done as a control
(see panel A, lane 1), and then the gel was blotted onto DEAE (B) and
nitrocellulose (C and D) membranes. The nitrocellulose membranes were
subsequently probed with a monoclonal antibody specific for IE86 (see
Materials and Methods). U373-IE86 extracts and recombinant IE86 protein
(rIE86) alone were used as controls in EMSA-Western blot analysis (D).
Arrows indicate the IR1 DNA-binding complex (A and B) and IE86 protein
present in the IR1 DNA-binding complex (C and D).
|
|
There remained the question of whether IE86 binds to the IR1 element
directly or indirectly. To address the possibility of
direct binding,
we performed an EMSA using two well-characterized
IE86-binding
sequences, CRS and EAIE2, as competitor oligonucleotides.
It has been
shown that the IE86 protein efficiently binds to these
two sites in in
vitro biochemical assays. If the IE86 DNA-binding
domain associates
directly with the IR1 element, one would expect
to see competition when
excess amounts of the CRS or EAIE2 oligonucleotides
are used. As shown
in Fig.
8, neither wild-type nor mutant
CRS
or EAIE2 oligonucleotides could compete with the IR1 complex (lanes
6 to 9). However, the wild-type IR1, but not the mutant
oligonucleotide,
efficiently competed with the DNA-binding complex. The
inability
of the CRS and EAIE2 oligonucleotides to outcompete the IR1
DNA-binding
complex could be due to their having lower binding
affinities.
However, the lack of a decrease in the IR1 DNA-binding
complex
suggests that the DNA-binding domain of the IE86 protein may
not
be required for its participation in the IR1 DNA-binding complex.
It is thus possible that association of IE86 with the IR1 DNA
response
element occurs through a cellular factor.
View larger version (73K):
[in this window]
[in a new window]
|
FIG. 8.
Neither CRS nor EAIE2 IE86 cis elements can
compete with the IR1-DNA complex. Nuclear extracts isolated from the
U373-IE86 stable cell line were incubated with a radiolabeled IR1
oligonucleotide and a 50-fold excess of unlabeled CRS or EAIE2
competitor oligonucleotides as indicated. The arrow indicates the IR1
complex. wt, wild type; mut, mutant.
|
|
Cellular transcription factor Sp1 binds to the IR1 DNA
element.
The results presented above suggest that the IE86 protein
may associate with a cellular factor(s) to form a complex on the IR1
DNA element. We then proceeded to determine which cellular factor(s) is
present in the complex. By computer analysis of the pol
promoter sequence, we found that the IR1 element has similarity to the
Sp1 cellular transcription factor binding site. Therefore, we conducted
a competition experiment using the Sp1 consensus oligonucleotide and an
antibody specific for Sp1 to elucidate whether the cellular
transcription factor was involved in IE86-mediated IR1 complex
formation. Oligonucleotides representing binding sites for CREB and ATF
and antibodies specific for these transcription factors were used to
broaden the survey. As indicated in Fig. 9, both IR1 and Sp1 consensus
oligonucleotides (Fig. 9A, lanes 2 and 4, respectively) efficiently
competed with the IR1 complex and Sp1 antibody supershifted the IR1
complex (Fig. 9B, lane 4). However, the CREB consensus oligonucleotide
(Fig. 9A, lane 3) could not compete with the IR1 complex. The ATF and
CREB antibodies did not supershift or disrupt the IR1 DNA-binding
complex (Fig. 9B, lanes 2 and 3). These results indicate that the
transcription factor Sp1 is in the IE86-mediated IR1 DNA-binding
complex. Therefore, we conclude that Sp1 and IE86 are components of the
IR1 DNA-binding complex.
View larger version (72K):
[in this window]
[in a new window]
|
FIG. 9.
The cellular transcription factor Sp1 binds to the IR1
element. U373-IE86 nuclear extracts were incubated with a radiolabeled
IR1 oligonucleotide and a 50-fold excess of unlabeled IR1, CREB, or Sp1
competitor oligonucleotides (panel A, lanes 2 to 4, respectively) or 1 µg of polyclonal antibodies specific for ATF, CREB, or Sp1 (panel B,
lanes 2 to 4, respectively). U373-IE86 nuclear extract alone was used
as a control (lanes 1). The unlabeled arrows indicate specific
complexes. SS, supershifted complex.
|
|
A repressor activity present in HeLa cells inhibits IE86-mediated
binding of DNA by Sp1.
Sp1 was initially identified as a HeLa
cell-derived factor (4, 23). Therefore, the following
question remained: why was there no significant IE86-mediated
transactivation of the pol promoter in HeLa cells? To
address this question, we compared the DNA binding activity of Sp1 in
U373-IE86 and HeLa-IE86 cells, using an Sp1 consensus oligonucleotide.
The parental U373MG and HeLa cells were used as controls. As indicated
in Fig. 10A, strong DNA binding was
detected in U373-IE86 nuclear extracts (lane 3). The Sp1 consensus
oligonucleotide specifically competed with this DNA-binding activity
(Fig. 10B, lane 4), and this activity was supershifted by Sp1 antibody
(Fig. 10B, lane 8). However, no DNA binding activity was detected for
Sp1 in parental U373MG nuclear extracts (Fig. 10A, lane 2), indicating
that the DNA binding activity of Sp1 was induced in the presence of
IE86 protein. To address whether this IE86-modulated binding of DNA by
Sp1 resulted from upregulation of Sp1 protein expression or enhancement
of its DNA binding ability, we performed a Western blot analysis to
measure Sp1 protein levels. However, no significant differences between the Sp1 protein levels of U373-IE86 and parental U373MG, HeLa, and
HeLa-IE86 cells were found (data not shown), suggesting that the
enhanced DNA binding activity of Sp1 in U373-IE86 cells was not due to
increased protein levels. Surprisingly, we were unable to detect Sp1
binding in either HeLa-IE86 or parental HeLa cells (Fig. 10A, lane 5 and 6, and data not shown), suggesting that a factor(s) present in HeLa
cells competed with Sp1 for its DNA binding.
View larger version (66K):
[in this window]
[in a new window]
|
FIG. 10.
IE86 protein enhances the DNA binding activity of Sp1.
(A) U373MG (lane 2), U373-IE86 (lane 3), HeLa (lane 5), and HeLa-IE86
(lane 6) cell nuclear extracts were incubated with a radiolabeled Sp1
consensus oligonucleotide. (B) U373-IE86 nuclear extracts were
incubated with the same Sp1 probe and a 50-fold excess of an unlabeled
oligonucleotide (oligo) or polyclonal antibodies (Ab) as indicated. The
unlabeled arrows indicate the Sp1 DNA-binding complex. SS, supershifted
complex.
|
|
The Sp3 protein has been shown to compete with the Sp1 protein for the
same DNA binding site (
15). However, we were unable
to
detect Sp3 activity in the DNA-protein complexes formed in
both HeLa
and HeLa-IE86 extracts (data not shown). Another possibility
is that a
repressor activity present in HeLa cells inhibits the
Sp1 binding
activity. This would probably explain why the IE86
protein was unable
to transactivate the
pol promoter in HeLa cells.
In this
case, one would expect to see competition between Sp1
and this
repressor for DNA binding. Therefore, we performed a
competition
experiment by individually titrating HeLa and HeLa-IE86
nuclear
extracts to analyze whether they inhibited the IE86-mediated
DNA
binding activity of Sp1 in U373-IE86 nuclear extracts. As
shown in Fig.
11A, the IE86-mediated Sp1-DNA binding
to the IR1
probe was gradually inhibited by increasing amounts of
either
HeLa (compare lane 1 to lanes 2 to 4) or HeLa-IE86 (compare lane
1 to lanes 5 to 7) nuclear extract. A similar experiment performed
with
an Sp1 probe yielded an identical result (Fig.
11B). However,
neither
parental U373 nor U373-IE86 nuclear extract could inhibit
the formation
of IE86-induced Sp1 DNA-binding complex (data not
shown). Overall,
these data indicate that the repressor activity
present in HeLa cells
inhibits the IE86-mediated DNA binding activity
of Sp1.
View larger version (89K):
[in this window]
[in a new window]
|
FIG. 11.
The factor(s) present in HeLa cells inhibits
IE86-mediated DNA-binding activity of Sp1. U373-IE86 nuclear extract
(2.5 µg) was incubated with radiolabeled IR1 (A) or Sp1 (B) consensus
oligonucleotides, respectively. Increasing amounts of HeLa (lanes 2 to
4) or HeLa-IE86 (lanes 5 to 7) nuclear extract were added as indicated.
U373-IE86 nuclear extract plus probe was used as a control (Lanes 1).
The arrows indicate Sp1 DNA-binding complex.
|
|
| |
DISCUSSION |
This study demonstrates that IE86 is one of the essential
regulatory proteins involved in the transactivation of the HCMV pol promoter in permissive U373MG cells. Comparison of
HCMV-permissive U373MG and HFF cells with HCMV-nonpermissive HeLa and
C33-A cells showed that the activation of the pol promoter
by IE86 was restricted to the permissive cells. EMSA analysis suggested
that IE86-mediated DNA binding of the cellular transcription factor Sp1
may be involved in transactivation of the pol promoter.
However, a repressor activity present in HeLa cells prevented this
Sp1-DNA binding, which may explain the inhibition of IE86-mediated
transactivation of the pol promoter in HeLa cells.
The molecular mechanism of cell permissiveness in HCMV infection
remains unknown. The gene expression cascade of HCMV initiates with the
expression of the major IE gene. It has been shown that transcription
from the major IE gene promoter (MIEP) is different in permissive and
nonpermissive cells (39). Recently, Baskar and coworkers
(2) provided evidence that the MIEP is regulated in a
tissue-specific manner. The majority of tissue and cell types which
display MIEP activity parallel tissues naturally infected by HCMV in
the human host. Interestingly, many HCMV-infected human cells observed
in vivo as well as infected nonpermissive rodent cell culture systems
display abundant synthesis of the IE1 and IE2 regulatory proteins, but
apparently without concomitant expression of other viral gene products.
These observations suggest that sequential gene expression is blocked
in an IE protein-independent way. This raises the question of why IE
proteins are unable to activate early and late gene expression and
suggests a potential mechanism involved in cell permissiveness of HCMV
infection.
It is possible that early gene activation mediated by IE or other viral
proteins (25) may require a cell- or tissue-specific factor(s) or the functional modification of a cellular transcription factor(s). It has been demonstrated that the pattern of HCMV infection in cultured epithelial and monocyte/macrophage cells is strikingly different from that in cultured fibroblasts (10, 13, 37). The HCMV genome can exist within those cells for prolonged periods with
little or no viral gene expression. When the cells reach a certain
stage of differentiation, the IE, early, and late genes are expressed
sequentially (57). It has been speculated that accessory
regulatory proteins may be required for triggering of full lytic-cycle
progression in certain cell types as well as for reactivation of latent
infections (6). These results suggest that cell
differentiation and stimulation may induce cell- or tissue-specific
factors which are required for sequential viral gene activation. Here
we have provided evidence that the HCMV regulatory protein IE86 is able
to modulate binding of DNA by the cellular transcription factor Sp1.
This functional change in DNA binding activity may be induced by an
interaction between Sp1 and the IE86 protein or by a posttranslational
modification of Sp1 induced by IE86. Recently, Yurochko and colleagues
(64) demonstrated in an in vitro assay using HEL fibroblasts
that IE86 enhances Sp1-DNA binding. These data suggest that the viral
regulatory protein may modulate the cellular machinery which mediates
early gene activation in both moderately permissive U373MG cells and fully permissive HEL fibroblasts. Interestingly, they also found that
viral infection upregulates Sp1 gene expression. In our study, we were
unable to detect an increase in expression of the Sp1 protein. This
difference suggests that IE86 itself does not induce expression of the
Sp1 protein. Nevertheless, the viral infection event and/or viral
regulatory proteins could modify the function of cellular transcription
factors, thereby stimulating the sequential gene expression events
associated with HCMV productive infection.
Alternatively, early gene promoters may be inhibited by a cell- or
tissue-specific repressor(s). Huang and Stinski (18) recently demonstrated that a cellular repressor protein is present in
abundance in nonpermissive HeLa cells. Binding of the cellular repressor protein to the upstream cis-acting negative
regulatory element correlates with repression of transcription from the
HCMV early UL4 promoter. Here we have provided further evidence that an
activity present in HeLa cells significantly decreases IE86-mediated binding of DNA by Sp1. This repressor activity may compete with the
IE86-mediated Sp1-IR1 binding activity directly or indirectly. It has
been shown that Sp1 is heavily modified posttranslationally (19,
20). However, the mechanism involved in control of Sp1 activity
is not completely understood. Nevertheless, our data suggest that a
cell-specific repressor activity may be involved in the inhibition of
HCMV early gene activation by IE86 in nonpermissive HeLa cells. This
effect appears to be specific for the IR1 element of the pol
promoter, since IE86 transactivates the pol promoter equally
well in permissive U373MG and HFF cells. It is possible that this
mechanism has a general role in cell permissiveness to HCMV infection.
Overall, early gene activation depends on the appropriate interaction
between IE gene products and cellular transcription factors. However,
the effects of IE proteins on early gene activation may be inhibited in
certain cell types. This event would block the viral gene expression
cascade that is necessary for productive infection. Since expression of
early genes is required for viral DNA replication (17, 44),
it is likely that their activation by IE proteins and other viral
proteins (25) is also essential for cell permissivity. On
the other hand, permissive cells may have a positive transcriptional
regulatory factor(s) which is required for IE86-mediated
transactivation. This factor(s) may negate the repressive effect of
putative repressor factors on the HCMV gene expression cascade.
On the surface, the recent report by Luu and Flores (32) may
appear to contradict our results. However, close examination suggests
otherwise. Luu and Flores showed that there was a 7- to 10-fold
activation of the pol promoter by the RL45 expression vector
in HeLa cells. Indeed, we detected a similar activation of the
pol promoter by the analogous IE gene expression vector pSVH
in HeLa cells. In contrast, we have consistently found that pSVH
transactivates the pol promoter in U373MG cells 160-fold. Therefore, we suggest that the finding of Luu and Flores that the
association of Sp1 with viral IE proteins may play an important role in
regulation of the pol gene transcription does support our
data.
In summary, our results showed that IE86, in association with other
viral as well as cellular proteins, may play a critical role in the
activation of the HCMV pol promoter in permissive U373MG
cells. This synergistic activation may require the functional modulation of the cellular transcription factor Sp1. Interestingly, we
found that an activity present in nonpermissive HeLa cells inhibits
IE86-mediated formation of the IE86-Sp1-IR1 DNA-binding complex. The
cell-specific transactivation by IE86 suggests that early gene
activation may also play a role in determining cell permissiveness.
Identification of the factors responsible for cell-specific activation
or inhibition of the HCMV genes should yield insight into the molecular
mechanism of host cell restriction characteristic of the life cycle of
HCMV.
| |
ACKNOWLEDGMENTS |
We thank Peter Ghazal for the RSV IE gene expression constructs,
pCM1058, and recombinant IE86 protein and Richard M. Stenberg for
plasmid pSVH. We also thank Bernd Stein, Robert Kovelman, and John
Westwick for helpful comments and critical reviews of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Signal
Pharmaceuticals, Inc., 5555 Oberlin Dr., San Diego, CA 92121. Phone:
(619) 558-7500, ext. 144. Fax: (619) 558-7513. E-mail:
jwu{at}signalpharm.com.
| |
REFERENCES |
| 1.
|
Arlt, H.,
D. Lang,
S. Gebert, and T. Stamminger.
1994.
Identification of binding sites for the 86-kilodalton IE2 protein of human cytomegalovirus within an IE2-responsive viral early promoter.
J. Virol.
68:4117-4125[Abstract/Free Full Text].
|
| 2.
|
Baskar, J. F.,
P. P. Smith,
G. Nilaver,
R. A. Jupp,
S. Hoffmann,
N. J. Peffer,
D. J. Tenney,
A. M. Colberg-Poley,
P. Ghazal, and J. A. Nelson.
1996.
The enhancer domain of the human cytomegalovirus major immediate-early promoter determines cell type-specific expression in transgenic mice.
J. Virol.
70:3207-3214[Abstract].
|
| 3.
|
Boshart, M.,
F. Weber,
G. Jahn,
K. Dorsch-Hasler,
B. Fleckenstein, and W. Schaffner.
1985.
A very strong enhancer is located upstream of an immediate early gene of human cytomegalovirus.
Cell
41:521-530[Medline].
|
| 4.
|
Briggs, M. R.,
J. T. Kadonaga,
S. P. Bell, and R. Tjian.
1986.
Purification and biochemical characterization of the promoter-specific transcription factor.
Science
234:47-52[Abstract/Free Full Text].
|
| 5.
|
Chang, C.-P.,
C. L. Malone, and M. F. Stinski.
1989.
A human cytomegalovirus early gene has three inducible promoters that are regulated differentially at various times after infection.
J. Virol.
63:281-290[Abstract/Free Full Text].
|
| 6.
|
Colberg-Poley, A. M.,
L. D. Santomenna,
P. P. Harlow,
P. A. Benfield, and D. J. Tenney.
1992.
Human cytomegalovirus US3 and UL36-38 immediate-early proteins regulate gene expression.
J. Virol.
66:95-105[Abstract/Free Full Text].
|
| 7.
|
DeMarchi, J. M.
1981.
Human cytomegalovirus DNA: restriction enzyme cleavage and map location for immediate early, early and late RNAs.
Virology
114:23-28[Medline].
|
| 8.
|
DeMarchi, J. M.,
C. A. Schmidt, and A. S. Kaplan.
1980.
Pattern of transcription of human cytomegalovirus in permissively infected cells.
J. Virol.
35:277-286[Abstract/Free Full Text].
|
| 9.
|
Depto, A. S., and R. M. Stenberg.
1989.
Regulated expression of the human cytomegalovirus pp65 gene: octamer sequence in the promoter is required for activation by viral gene products.
J. Virol.
63:1232-1238[Abstract/Free Full Text].
|
| 10.
|
Detrick, B.,
J. Rhame,
Y. Wang,
C. N. Nagineni, and J. J. Hooks.
1996.
Cytomegalovirus replication in human retinal pigment epithelial cells: altered expression of viral early proteins.
Invest. Ophthalmol. Vis. Sci.
37:814-825[Abstract/Free Full Text].
|
| 11.
|
Dignam, J. D.,
R. M. Lebovitz, and R. G. Roeder.
1983.
Accurate transcription initiation by RNA polymerase II in a soluble extract from isolated mammalian nuclei.
Nucleic Acids Res.
11:1475-1489[Abstract/Free Full Text].
|
| 12.
|
Fiala, M.,
J. E. Payne,
T. V. Berne, et al.
1975.
Epidemiology of cytomegalovirus infection after transplantation and immunosuppression.
J. Infect. Dis.
132:421-433[Medline].
|
| 13.
|
Fish, K. N.,
W. Britt, and J. A. Nelson.
1996.
A novel mechanism for persistence of human cytomegalovirus in macrophage.
J. Virol.
70:1855-1862[Abstract].
|
| 14.
|
Furnari, B. A.,
E. Poma,
T. F. Kowalik,
S.-M. Huong, and E.-S. Huang.
1993.
Human cytomegalovirus immediate-early gene 2 protein interacts with itself and with several novel cellular proteins.
J. Virol.
67:4981-4991[Abstract/Free Full Text].
|
| 15.
|
Hagen, G.,
S. Muller,
M. Beato, and G. Suske.
1994.
Sp1-mediated transcriptional activation is repressed by Sp3.
EMBO J.
13:3843-3851[Medline].
|
| 16.
|
Hermiston, T. W.,
C. L. Malone,
P. R. Witte, and M. F. Stinski.
1987.
Identification and characterization of the human cytomegalovirus immediate-early region 2 gene that stimulates gene expression from an inducible promoter.
J. Virol.
61:3214-3221[Abstract/Free Full Text].
|
| 17.
|
Huang, E. S., and T. F. Kowalik.
1993.
The pathogenicity of human cytomegalovirus, p. 3-45. In
Y. Becker, G. Darai, and E.-S. Huang (ed.), Molecular aspects of human cytomegalovirus diseases.
Springer-Verlag, Berlin, Germany.
|
| 18.
|
Huang, L., and M. F. Stinski.
1995.
Binding of cellular repressor protein or the IE2 protein to a cis-acting negative regulatory element upstream of a human cytomegalovirus early promoter.
J. Virol.
69:7612-7621[Abstract].
|
| 19.
|
Jackson, S. P.,
J. J. MacDonald,
S. Lees-Miller, and R. Tjian.
1990.
GC box binding induces phosphorylation of Sp1 by a DNA-dependent protein kinase.
Cell
63:155-165[Medline].
|
| 20.
|
Jackson, S. P., and R. Tjian.
1988.
O-Glycosylation of eukaryotic transcription factors: implication for mechanism of transcriptional regulation.
Cell
55:125-133[Medline].
|
| 21.
|
Jacobson, M. A., and J. Mills.
1988.
Serious cytomegalovirus disease in the acquired immunodeficiency syndrome (AIDS). Clinical findings, diagnosis, and treatment.
Ann. Intern. Med.
108:585-594.
|
| 22.
|
Jahn, G.,
E. Knust,
H. Schmolla,
T. Sarre,
J. A. Nelson,
J. K. McDougall, and B. Fleckenstein.
1984.
Predominant immediate-early transcripts of human cytomegalovirus AD 169.
J. Virol.
49:363-370[Abstract/Free Full Text].
|
| 23.
|
Kadonaga, J. T.,
K. R. Carner,
F. R. Masiarz, and R. Tjian.
1987.
Isolation of cDNA encoding transcription factor Sp1 and analysis of the DNA binding domain.
Cell
51:1079-1090[Medline].
|
| 24.
|
Kerry, J. A.,
M. A. Priddy, and R. M. Stenberg.
1994.
Identification of sequence elements in the human cytomegalovirus DNA polymerase gene promoter required for activation by viral gene products.
J. Virol.
68:4167-4176[Abstract/Free Full Text].
|
| 25.
|
Kerry, J. A.,
M. A. Priddy,
T. Y. Jervey,
C. P. Kohler,
T. L. Staley,
C. D. Vanson,
T. R. Jones,
A. C. Iskenderian,
D. G. Anders, and R. M. Stenberg.
1996.
Multiple regulatory events influence human cytomegalovirus DNA polymerase (UL54) expression during viral infection.
J. Virol.
70:373-382[Abstract].
|
| 26.
|
Kerry, J. A.,
M. A. Priddy,
T. L. Staley,
T. R. Jones, and R. M. Stenberg.
1997.
The role of ATF in regulating the human cytomegalovirus DNA polymerase (UL54) promoter during viral infection.
J. Virol.
71:2120-2126[Abstract].
|
| 27.
|
Klucher, K. M.,
M. Sommer,
J. T. Kadonaga, and D. H. Spector.
1993.
In vivo and in vitro analysis of transcriptional activation mediated by the human cytomegalovirus major immediate-early proteins.
Mol. Cell. Biol.
13:1238-1250[Abstract/Free Full Text].
|
| 28.
|
Kouzarides, T.,
A. T. Bankier,
S. C. Satchwell,
E. Preddy, and B. G. Barrell.
1988.
An immediate early gene of human cytomegalovirus encodes a potential membrane glycoprotein.
Virology
165:151-164[Medline].
|
| 29.
|
Lang, D., and T. Stamminger.
1993.
The 86-kilodalton IE-2 protein of human cytomegalovirus is a sequence-specific DNA-binding protein that interacts directly with the negative autoregulatory response element located near the cap site of the IE-1/2 enhancer-promoter.
J. Virol.
67:323-331[Abstract/Free Full Text].
|
| 30.
|
Lang, D.,
S. Gebert,
H. Arlt, and T. Stamminger.
1995.
Functional interaction between the human cytomegalovirus 86-kilodalton IE2 protein and the cellular transcription factor CREB.
J. Virol.
69:6030-6037[Abstract].
|
| 31.
|
Lukac, D. M.,
J. R. Manuppello, and J. C. Alwine.
1994.
Transcriptional activation by the human cytomegalovirus immediate-early proteins: requirements for simple promoter structures and interactions with multiple components of the transcription complex.
J. Virol.
68:5184-5193[Abstract/Free Full Text].
|
| 32.
|
Luu, P., and O. Flores.
1997.
Binding of SP1 to the immediate-early protein-responsive element of the human cytomegalovirus DNA polymerase promoter.
J. Virol.
71:6683-6691[Abstract].
|
| 33.
|
Malone, C. L.,
D. H. Vesole, and M. F. Stinski.
1990.
Transactivation of a human cytomegalovirus early promoter by gene products from the immediate-early gene IE2 and augmentation by IE1: mutational analysis of the viral proteins.
J. Virol.
64:1498-1506[Abstract/Free Full Text].
|
| 34.
|
Marker, S. C.,
R. J. Howard,
R. L. Simmons, et al.
1981.
Cytomegalovirus infection: a quantitative prospective study of 320 consecutive renal transplants.
Surgery
89:660-671[Medline].
|
| 35.
|
McDonough, S. H., and D. H. Spector.
1983.
Transcription in human fibroblasts permissively infected by human cytomegalovirus strain AD169.
Virology
125:31-46[Medline].
|
| 36.
|
Meyer, J. D.,
H. C. Spencer, Jr.,
J. C. Watts, et al.
1975.
Cytomegalovirus pneumonia after human marrow transplantation.
Ann. Intern. Med.
82:181-188.
|
| 37.
|
Minton, E. J.,
C. Tysoe,
J. H. Sinclair, and J. G. P. Sissons.
1994.
Human cytomegalovirus infection of the monocyte/macrophage lineage in bone marrow.
J. Virol.
68:4017-4021[Abstract/Free Full Text].
|
| 38.
|
Moreira, J. L.,
M. Wirth,
M. Fitzek, and H. Hauser.
1992.
Evaluation of reporter genes in mammalian cell lines.
Methods Mol. Cell. Biol.
3:23-29.
|
| 39.
|
Nelson, J. A.,
C. Reynolds-Kohler, and B. A. Smith.
1987.
Negative and positive regulation by a short segment in the 5'-flanking region of the human cytomegalovirus major immediately-early gene.
Mol. Cell. Biol.
7:4125-4129[Abstract/Free Full Text].
|
| 40.
|
Pizzorno, M. C.,
M.-A. Mullen,
Y.-N. Chang, and G. S. Hayward.
1991.
The functionally active IE2 immediate-early regulatory protein of human cytomegalovirus is an 80-kilodalton polypeptide that contains two distinct activator domains and a duplicated nuclear localization signal.
J. Virol.
65:3839-3852[Abstract/Free Full Text].
|
| 41.
|
Rubin, R. H.,
A. B. Cosimi,
N. E. Tolkoff-Rubin,
P. S. Russell, and M. S. Hirsch.
1977.
Infectious disease syndromes attributable to cytomegalovirus and their significance among renal transplant recipients.
Transplantation
24:458-464[Medline].
|
| 42.
|
Schwartz, R.,
M. H. Sommer,
A. Scully, and D. H. Spector.
1994.
Site-specific binding of the human cytomegalovirus IE2 86-kilodalton protein to an early gene promoter.
J. Virol.
68:5613-5622[Abstract/Free Full Text].
|
| 43.
|
Sommer, M. H.,
A. L. Scully, and D. H. Spector.
1994.
Transactivation by the human cytomegalovirus IE2 86-kilodalton protein requires a domain that binds to both the TATA box-binding protein and the retinoblastoma protein.
J. Virol.
68:6223-6231[Abstract/Free Full Text].
|
| 44.
|
Spaete, R. R., and E. S. Mocarski.
1985.
Regulation of cytomegalovirus gene expression: and promoters are trans activated by viral functions in permissive human fibroblasts.
J. Virol.
56:135-143[Abstract/Free Full Text].
|
| 45.
|
Spector, D. H.,
K. M. Klucher,
D. K. Rabert, and D. A. Wright.
1990.
Human cytomegalovirus early gene expression.
Curr. Top. Microbiol. Immunol.
154:21-45[Medline].
|
| 46.
|
Stango, S.,
R. F. Pass,
G. Cloud,
W. J. Britt,
R. E. Henderson,
P. D. Waltson,
D. A. Veren,
F. Page, and C. A. Alford.
1986.
Primary cytomegalovirus infection in pregnancy. Incidence, transmission to fetus and clinical outcome.
JAMA
256:1904-1908[Abstract/Free Full Text].
|
| 47.
|
Staprans, S. I.,
D. K. Rabert, and D. H. Spector.
1988.
Identification of sequence requirements and trans-acting functions necessary for regulated expression of a human cytomegalovirus early gene.
J. Virol.
62:3463-3473[Abstract/Free Full Text].
|
| 48.
|
Stenberg, R. M.
1993.
Immediate-early genes of human cytomegalovirus: organization and function, p. 330-359. In
Y. Becker, G. Darai, and E.-S. Huang (ed.), Molecular aspects of human cytomegalovirus diseases.
Springer-Verlag KG, Berlin, Germany.
|
| 49.
|
Stenberg, R. M.,
D. R. Thomsen, and M. F. Stinski.
1984.
Structural analysis of the major immediate early gene of human cytomegalovirus.
J. Virol.
49:190-199[Abstract/Free Full Text].
|
| 50.
|
Stenberg, R. M.,
P. R. Witte, and M. F. Stinski.
1985.
Multiple spliced and unspliced transcripts from human cytomegalovirus immediate-early region 2 and evidence for a common initiation site within immediate-early region 1.
J. Virol.
56:665-675[Abstract/Free Full Text].
|
| 51.
|
Stenberg, R. M.,
A. S. Depto,
J. Fortney, and J. A. Nelson.
1989.
Regulated expression of early and late RNAs and proteins from the human cytomegalovirus immediate-early gene region.
J. Virol.
63:2699-2708[Abstract/Free Full Text].
|
| 52.
|
Stenberg, R. M.,
J. Fortney,
S. W. Barlow,
B. P. Magrane,
J. A. Nelson, and P. Ghazal.
1990.
Promoter-specific trans activation and repression by human cytomegalovirus immediate-early proteins involves common and unique protein domains.
J. Virol.
64:1556-1565[Abstract/Free Full Text].
|
| 53.
|
Stinski, M. F.,
D. R. Thomsen,
R. M. Stenberg, and L. C. Goldstein.
1983.
Organization and expression of the immediate early genes of human cytomegalovirus.
J. Virol.
46:1-14[Abstract/Free Full Text].
|
| 54.
|
Tenney, D. J., and A. M. Colberg-Poley.
1991.
Expression of the human cytomegalovirus UL36-38 immediate early region during permissive infection.
Virology
182:199-210[Medline].
|
| 55.
|
Tenney, D. J., and A. M. Colberg-Poley.
1991.
Human cytomegalovirus UL36-38 and US3 immediate-early genes: temporally regulated expression of nuclear, cytoplasmic, and polysome-associated transcripts during infection.
J. Virol.
65:6724-6734[Abstract/Free Full Text].
|
| 56.
|
Thomsen, D. R.,
R. M. Stenberg,
W. F. Goins, and M. F. Stinski.
1984.
Promoter-regulatory region of the major immediate early gene of human cytomegalovirus.
Proc. Natl. Acad. Sci. USA
81:659-663[Abstract/Free Full Text].
|
| 57.
|
Tsutsui, Y., and T. Nogami-Satake.
1990.
Differential expression of the major immediate early gene of human cytomegalovirus.
J. Gen. Virol.
71:115-124[Abstract/Free Full Text].
|
| 58.
|
Wathen, M. W., and M. F. Stinski.
1982.
Temporal patterns of human cytomegalovirus transcription: mapping the viral RNAs synthesized at immediate early, early, and late times after infection.
J. Virol.
41:462-477[Abstract/Free Full Text].
|
| 59.
|
Wathen, M. W.,
D. R. Thomsen, and M. F. Stinski.
1981.
Temporal regulation of human cytomegalovirus transcription at immediate early and early times after infection.
J. Virol.
38:446-459[Abstract/Free Full Text].
|
| 60.
|
Weston, K.
1988.
An enhancer element in the short unique region of human cytomegalovirus regulates the production of a group of abundant immediate early transcripts.
Virology
162:406-416[Medline].
|
| 61.
|
Wilkinson, G. W. G.,
A. Akrigg, and P. J. Greenaway.
1984.
Transcription of the immediate early genes of human cytomegalovirus strain AD169.
Virus Res.
1:101-116[Medline].
|
| 62.
| Wu, J., and M. S. Barbosa. Unpublished data.
|
| 63.
|
Yurochko, A. D.,
T. F. Kowalik,
S.-M. Huong, and E.-S. Huang.
1995.
Human cytomegalovirus upregulates NF-B activity by transactivating the NF-B p105/p50 and p65 promoters.
J. Virol.
69:5391-5400[Abstract].
|
| 64.
|
Yurochko, A. D.,
M. W. Mayo,
E. E. Poma,
A. S. Baldwin, Jr., and E.-S. Huang.
1997.
Induction of the transcription factor Sp1 during human cytomegalovirus infection mediates upregulation of the p65 and p105/p50 NF-B promoters.
J. Virol.
71:4638-4648[Abstract].
|
J Virol, January 1998, p. 236-244, Vol. 72, No. 1
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Sanders, R. L., Clark, C. L., Morello, C. S., Spector, D. H.
(2008). Development of Cell Lines That Provide Tightly Controlled Temporal Translation of the Human Cytomegalovirus IE2 Proteins for Complementation and Functional Analyses of Growth-Impaired and Nonviable IE2 Mutant Viruses. J. Virol.
82: 7059-7077
[Abstract]
[Full Text]
-
Poole, E., Atkins, E., Nakayama, T., Yoshie, O., Groves, I., Alcami, A., Sinclair, J.
(2008). NF-{kappa}B-Mediated Activation of the Chemokine CCL22 by the Product of the Human Cytomegalovirus Gene UL144 Escapes Regulation by Viral IE86. J. Virol.
82: 4250-4256
[Abstract]
[Full Text]
-
Chiou, S.-H., Yang, Y.-P., Lin, J.-C., Hsu, C.-H., Jhang, H.-C., Yang, Y.-T., Lee, C.-H., Ho, L. L. T., Hsu, W.-M., Ku, H.-H., Chen, S.-J., Chen, S. S.-L., Chang, M. D. T., Wu, C.-W., Juan, L.-J.
(2006). The Immediate Early 2 Protein of Human Cytomegalovirus (HCMV) Mediates the Apoptotic Control in HCMV Retinitis through Up-Regulation of the Cellular FLICE-Inhibitory Protein Expression. J. Immunol.
177: 6199-6206
[Abstract]
[Full Text]
-
Kronschnabl, M., Stamminger, T.
(2003). Synergistic induction of intercellular adhesion molecule-1 by the human cytomegalovirus transactivators IE2p86 and pp71 is mediated via an Sp1-binding site. J. Gen. Virol.
84: 61-73
[Abstract]
[Full Text]
-
Chen, J., Stinski, M. F.
(2002). Role of Regulatory Elements and the MAPK/ERK or p38 MAPK Pathways for Activation of Human Cytomegalovirus Gene Expression. J. Virol.
76: 4873-4885
[Abstract]
[Full Text]
-
Shirakata, M., Terauchi, M., Ablikim, M., Imadome, K.-I., Hirai, K., Aso, T., Yamanashi, Y.
(2002). Novel Immediate-Early Protein IE19 of Human Cytomegalovirus Activates the Origin Recognition Complex I Promoter in a Cooperative Manner with IE72. J. Virol.
76: 3158-3167
[Abstract]
[Full Text]
-
Marchini, A., Liu, H., Zhu, H.
(2001). Human Cytomegalovirus with IE-2 (UL122) Deleted Fails To Express Early Lytic Genes. J. Virol.
75: 1870-1878
[Abstract]
[Full Text]
-
García-Ramírez, J. J., Ruchti, F., Huang, H., Simmen, K., Angulo, A., Ghazal, P.
(2001). Dominance of Virus over Host Factors in Cross-Species Activation of Human Cytomegalovirus Early Gene Expression. J. Virol.
75: 26-35
[Abstract]
[Full Text]
-
Chen, J., Stinski, M. F.
(2000). Activation of Transcription of the Human Cytomegalovirus Early UL4 Promoter by the Ets Transcription Factor Binding Element. J. Virol.
74: 9845-9857
[Abstract]
[Full Text]
-
Kim, J.-M., Hong, Y., Jeang, K.-T., Kim, S.
(2000). Transactivation activity of the human cytomegalovirus IE2 protein occurs at steps subsequent to TATA box-binding protein recruitment. J. Gen. Virol.
81: 37-46
[Abstract]
[Full Text]
Top
Abstract
Introduction
