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J Virol, April 1998, p. 2697-2707, Vol. 72, No. 4
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Separate DNA Elements Containing ATF/CREB and IE86
Binding Sites Differentially Regulate the Human Cytomegalovirus
UL112-113 Promoter at Early and Late Times in the
Infection
Steven M.
Rodems,
Charles L.
Clark, and
Deborah H.
Spector*
Department of Biology and Center for
Molecular Genetics, University of California, San Diego, La Jolla,
California 92093-0357
Received 18 November 1997/Accepted 23 December 1997
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ABSTRACT |
The human cytomegalovirus (HCMV) UL112-113 promoter represents a
useful model for studying temporal regulation of viral gene expression.
Stimulation of this promoter by the 86-kDa immediate-early protein
(IE86) is controlled by sequences between nucleotides 
113 and 59,
which include both an ATF/CREB and an IE86 binding site. In transient
assays, the ATF/CREB site is essential, and the IE86 site, although
nonessential, can enhance transcription. With recombinant viruses, we
have assessed the function of these promoter elements in the context of
the viral genome. Transcription from the inserted UL112-113 promoter
shows the same temporal pattern as the endogenous promoter, including
the switch to an upstream RNA start site late in infection. Deletion of
sequences containing the IE86 site results in a decrease in the level
of early transcription and elimination of late transcription. In
contrast, when the ATF/CREB site is deleted, early RNA synthesis is
almost completely abolished, but late transcription is comparable to
that of the wild type, with repositioning of the RNA start site
downstream by the number of nucleotides deleted. Replacement of
sequences between 108 and 95 with the HCMV
cis-repression signal from the major immediate-early promoter had no effect on the level of late RNAs but resulted in the
repositioning of the RNA start site 39 nucleotides upstream. These
results suggest that the ATF/CREB site is functional only at early
times, while sequences containing the IE86 site modulate the level of
early RNAs and may be required for activating late transcription in a
distance-dependent manner.
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INTRODUCTION |
Human cytomegalovirus (HCMV), a
member of the betaherpesvirus family, is an important opportunistic
pathogen in immunocompromised individuals and is recognized as a major
viral cause of birth defects in newborns (2). As for other
herpesviruses, HCMV genes are expressed in a temporal pattern upon
infection (5, 18, 29, 34, 35). Members of the
immediate-early (IE) class of genes are expressed upon viral infection
and do not require de novo protein synthesis for production of their
RNAs. Several of the IE proteins are transactivators of the products of
the next class of genes, the early genes. Concomitant with viral DNA
replication, there is expression of the late class of viral genes,
whose protein products are generally involved in viral genome packaging
and virion maturation. Since several of the early gene protein products are essential for viral DNA replication, understanding the control of
early viral gene expression is important for designing therapeutic strategies to inhibit viral replication.
In order to understand the mechanisms that control early viral gene
expression, several laboratories have studied a number of different
early viral promoters by various types of transcription assays (for
reviews, see references 20 and
26). To date, the most common assay to study viral
promoter activity has been the transient expression assay. In this
assay, a plasmid containing a reporter gene under control of an early
viral promoter is transfected into cells along with expression plasmids
encoding HCMV transcriptional regulatory proteins. These assays have
proven useful in determining which promoter sequences are important for
gene expression as well as which HCMV proteins behave as
transcriptional regulators. In fact, these assays have identified the
HCMV IE2 86-kDa protein (IE86) and the IE1 72-kDa protein (IE72) as the
major transregulators of early viral gene expression (for reviews, see
references 20 and 26). However,
transient expression assays are limited in that they do not provide
accurate information about the regulatory events that occur during a
normal viral infection. Several labs have attempted to circumvent this
issue by transfecting cells with plasmid and subsequently
superinfecting with virus (3, 10, 25, 27, 32). Although this
allows one to study gene expression in infected cells, there remain
template-specific differences between plasmid DNA and viral DNA. In
particular, the late induction of the 1.2-kb RNA promoter, normally
observed in infected cells, does not occur when the promoter is located
on a plasmid in transfection-infection assays unless an HCMV origin of
replication, oriLyt, is also included on the plasmid (33).
In addition, it was shown that at least two genes, UL83 and UL99, with
early-late and true late kinetics, respectively, were activated earlier
and to higher levels in transfection-infection assays than observed
with the endogenous genes during a normal infection (14). In
an attempt to study early and late viral gene expression without the
inaccuracies associated with transfection assays, Kohler et al. have
used a gene replacement strategy based on the finding that a portion of
the unique short region of the HCMV genome is dispensable for viral
growth (14). To this end, they have constructed recombinant
viruses in which a viral promoter linked to a reporter gene is inserted
between the US9 and US10 genes and have shown that the inserted
promoters exhibit kinetics similar to those of the endogenous viral
promoters.
As a model for early HCMV gene expression, our laboratory has studied
the expression of the 2.2-kb class of RNAs (open reading frame
UL112-113) which encode a family of nuclear phosphoproteins (13,
27, 28, 36, 37). Although the function of these proteins is
unclear, there is evidence that they behave as transcriptional activators and are required for viral DNA replication (7, 10, 21). By transient expression analysis, our laboratory has shown that activation of the UL112-113 promoter is mediated through a major
regulatory domain between nucleotides 113 and 59 (23, 24). This region contains a weak binding site for the HCMV
transactivator IE86 (113 to 85) and a consensus ATF/CREB binding
site (71 to 66) (15, 23, 24). In addition, the UL112-113
promoter contains three other binding sites for IE86 (286 to 257,
248 to 218, and 148 to 120) (1, 24). Results of
mutational analyses of the UL112-113 promoter suggest that in
transfection assays, the ATF/CREB site is the major regulatory element
upstream of the TATA box, whereas the IE86 binding sites play an
accessory role (1, 15, 23, 24).
The goal of this study was to determine the functions of various
sequence elements within the UL112-113 promoter at different times
during HCMV infection. To this end, we have further defined the roles
of the sequences containing the ATF/CREB binding site and the weak IE86
binding site within the UL112-113 promoter at early and late times
during infection. We have constructed recombinant viruses in which
various mutations of the UL112-113 promoter, linked to the
chloramphenicol acetyltransferase (CAT) gene, were inserted between the
US9 and US10 genes in the viral genome and have analyzed UL112-113
promoter-CAT activity at different times during the infection. We find
that the kinetics of expression of the UL112-113 promoter from the
US9/10 locus are identical to that of the endogenous viral promoter,
including the switch to a different RNA start site late in infection
(28). Consistent with transient expression data, our results
demonstrate that the sequences containing the ATF/CREB site play a
major role in UL112-113 promoter activity early during viral infection,
whereas the region containing the weak IE86 binding site has a moderate
effect on transcription. However, at late times in the infection, we
find that the ATF/CREB site plays little if any role in expression, but
the sequences between 113 and 85, which include the weak IE86
binding site, are required for transcription from the late RNA start
site within the UL112-113 promoter. Furthermore, replacement of the
region between nucleotides 108 and 95 with the HCMV
cis-repression signal (CRS) indicated that the sequences
between 108 and 95 play a role in distance-dependent, and possibly
orientation-dependent, late transcription initiation from the UL112-113
promoter. These data underscore the value of using recombinant viruses
to study viral promoter activity and demonstrate that different
promoter regulatory elements are employed at early and late times in
the infection.
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MATERIALS AND METHODS |
Cells and virus.
Human foreskin fibroblasts (FF cells) were
maintained in minimum essential medium with Earle's salts containing
10% fetal bovine serum. HCMV Towne strain was obtained from American
Type Culture Collection. Methods for cell culture and viral infection have been described elsewhere (30). All infections were
performed with a multiplicity of infection of 3 to 10.
Molecular cloning.
Sequences used to facilitate homologous
recombination into the HCMV US9/10 locus were derived from a 3.4-kb
EcoRI-HindIII fragment from
pHCMV-EcoRI-B (30). The 3.4-kb fragment was cut with SalI and end repaired with Klenow enzyme, and ligated
to HindIII linkers, and the resulting 2.7-kb fragment
was ligated into pGem-3Z at HindIII to give pGem-US9/10.
Two oligonucleotides (5'-CAGATCTGCGGCCGCAGGCC-3' and
5'-TGCGGCCGCAGATCTGGGCC-3') were annealed, resulting in a
20-bp ApaI fragment containing internal BglII and
NotI sites which was subsequently ligated into the
ApaI site of pGem-US9/10. The resulting plasmid was cut with
BglII, and a 4.8-kb BamHI fragment from pON855
(31), containing the lacZ and guanine
phosphoribosyltransferase (gpt) genes, was inserted to give
rise to pUS9/10-lacZ/gpt.
A 1.95-kb BamHI fragment from p358-CAT (27) was
end repaired with Klenow enzyme, ligated to NotI linkers,
and inserted at the NotI site of pUS9/10-lacZ/gpt to give
pUS9/10-358-CAT. p148-CAT (27), p119-CAT (previously
referred to as D [23]), and p148(
84-58)-CAT (previously referred to as Del [23]) were digested
with HindIII and BamHI, end repaired with
Klenow enzyme, ligated to NotI linkers, and inserted at the
NotI site of pUS9/10-lacZ/gpt to give pUS9/10-148-CAT, pUS9/10-119-CAT, and pUS9/10-148(84-58)-CAT, respectively.
p148(
84-58)CRS-CAT and p148(
84-58)IICRS-CAT were constructed by
using a QuickChange site-directed mutagenesis kit (Stratagene).
p148(
84-58)CRS-CAT was constructed according to the manufacturer's
protocol, using the two oligonucleotides
5'-CTAGAGTACCAGTCGTTTAGTGAACCGTACTGTTTAAGGG-3'
and
5'-CCCTTAAACAGTACGGTTCACTAAACGACTGGTACTCTAG-3' and the
plasmid
p148(
84-58)-CAT. p148(
84-58)IICRS-CAT was constructed
similarly,
using the two oligonucleotides
5'-GTTTAGTGAACCGTTTAGTGAACGGGTGTTGCTAGG-3'
and
5'-CCTAGCAACACCCGTTCACTAAACGGTTCACTAAAC-3' and the plasmid
p148(
84-58)CRS-CAT.
HindIII-
BamHI
fragments from p148(
84-58)CRS-CAT
and p148(
84-58)IICRS-CAT were
end repaired with Klenow enzyme,
ligated to
NotI linkers,
and inserted into the
NotI site of pUS9/10-lacZ/gpt
to give
pUS9/10-148(
84-58)CRS-CAT and pUS9/10-148(
84-58)IICRS-CAT,
respectively.
Recombinant virus construction.
All plasmids derived from
pUS9/10-lacZ/gpt were linearized with HindIII, and 30 µg was electroporated into 4 × 106 FF cells.
Twenty-four hours after electroporation, the cells were infected with
wild-type HCMV (Towne strain) at a multiplicity of infection of 5 to
10. Infections were allowed to proceed for 5 days, and virus was
harvested by clarifying the culture supernatant at 1,500 rpm for 5 min.
Virus was passaged three times under selection as follows. Briefly,
cells were infected, and the inoculum was removed 3 h later and
replaced with media containing 150 µM mycophenolic acid and 10 µM
xanthine. After 5 days, the supernatant was collected, the cells were
sonicated to release membrane-associated virus, and the supernatants
were combined. Virus was then added to fresh cells, and plaques were
stained with
5-bromo-4-chloro-3-indolyl-
-D-galactopyranoside (X-Gal;
0.5 mg/ml) to visualize recombinants. Recombinant viruses were
subsequently plaque purified two to three times. The purified virus was
then used to infect 5 × 105 cells. The viral
supernatant was used to further amplify the virus, and genomic DNA was
harvested from the cells to verify virus genotype by Southern blot
analysis.
Southern blot analysis.
Genomic DNA from mock or
virus-infected cells was isolated by using a QIAamp blood kit (Qiagen)
as described in the manufacturer's protocol. To confirm the presence
of the CAT gene in the recombinant viruses, genomic DNA was digested
with NotI and subjected to Southern blot analysis by using
standard methods. Blots were hybridized to a 32P-labeled,
551-bp HindIII-to-NcoI DNA fragment isolated
from pSV2-CAT (American Type Culture Collection) and subjected to
autoradiography. To test for purity of recombinant viruses and to
confirm insertion into the US9/10 locus, genomic DNA was digested with
EcoRI and NcoI, and Southern blot analysis was
performed with a 32P-labeled, 4.5-kb
EcoRI-to-NcoI DNA fragment isolated from
pHCMV-EcoRI-B.
Western blot analysis.
FF cells were infected with HCMV
recombinants and harvested at the indicated times by lysing directly in
Laemmli sample buffer. Lysates (104 cell equivalents) were
electrophoresed on 10% polyacrylamide protein gels and transferred to
Immobilon membranes (Millipore). Blocked membranes were incubated with
primary antibody BSA 2-9 (37), followed by incubation with a
horseradish peroxidase-coupled secondary antibody and detection with
chemiluminescence (Pierce) according to standard methods.
CAT enzyme assays and RNA primer extension analysis.
FF
cells were infected with HCMV recombinants, harvested at the indicated
times, and assayed for CAT enzyme as previously described
(27). CAT assays were quantitated by scintillation counting
or phosphorimager analysis.
For primer extension analysis, 7 × 10
6 FF cells were
infected with recombinant HCMV and harvested at the indicated times by
trypsinization. Total RNA was isolated from cell pellets by using
a
Qiagen RNeasy Midi kit. Primer extension reactions were performed
as
described previously by using a
32P-end-labeled
oligonucleotide complementary to CAT RNA (positions
+15 to +53 relative
to the ATG codon) and 50 µg of total RNA (
22).
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RESULTS |
Construction of recombinant HCMV.
The HCMV UL112-113 promoter
has been extensively studied by using plasmid transfections, in vitro
transcription, and DNase I footprint analyses (1, 13, 15, 23, 24,
27, 28, 36). However, these assays are limited in that certain
aspects of infection-specific viral gene regulation are absent. In
particular, late viral transcription is inaccurately represented in
plasmid transfections (14). To better understand the
regulation of the UL112-113 promoter during infection, we constructed
recombinant HCMV in which the UL112-113 promoter, linked to the CAT
gene, was inserted into the viral genome. The recombinant viruses were then used to analyze the role of various UL112-113 promoter elements throughout the infection.
The region containing the US1 to the US11 genes has been shown to be
dispensable for viral growth (
8,
9). Stable recombinant
HCMV
can be constructed by insertion of sequences between the
US9 and US10
genes through homologous recombination (
14). Therefore,
we
have used this technique to insert the UL112-113 promoter-CAT
sequences into the viral genome. We constructed several different
recombinant viruses containing previously uncharacterized site-directed
mutations as well as promoter mutations that have been previously
analyzed by transient expression analysis (Fig.
1). Recombinant
viruses were propagated
under GPT selection, and putative recombinants
were identified by X-Gal
staining as described in Materials and
Methods.
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FIG. 1.
UL112-113 promoters inserted into recombinant viruses.
(A) Sequences of the HCMV UL112-113 promoter from 113 to +1.
Previously identified regulatory elements are indicated by the shaded
boxes beneath the sequence. The IE86 binding site represents the
sequences protected by IE86 in a DNase I footprint analysis
(24), whereas the CREB/ATF and TATA sites are the respective
consensus sequences. (B) Map of UL112-113 promoter mutations used in
this study. The name of each recombinant virus is indicated at the
right. The weak IE86 binding site, CREB/ATF site, and TATA box are
indicated by shaded boxes. The black box indicates the replacement of
the weak IE86 binding site and/or adjacent A-T rich sequences with the
HCMV CRS from the major IE promoter. Dashed lines denote deleted
sequences. (C) Sequence between 113 and 85 in v148(84-58)-CAT,
v148(84-58)CRS-CAT, and v148(84-58)IICRS-CAT. Sequences protected
by IE86 in a DNase I footprint are indicated by the shaded box above
the sequence. Sequences outlined in black are those replaced in
v148(84-58)CRS-CAT and v148(84-58)IICRS-CAT. The CRS is indicated
by the bracket.
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The genotype of the recombinant viruses was confirmed by Southern blot
analysis (Fig.
2). To confirm the
presence of CAT sequences,
genomic DNA preparations from infected cells
were digested with
NotI, which should yield a fragment
containing the CAT gene and
the UL112-113 promoter. The size of this
fragment varies from
1.8 to 2.1 kb, depending on the promoter mutation
inserted. Southern
blots were probed with a
32P-labeled,
551-bp
HindIII-
NcoI DNA fragment containing
only CAT
sequences. As expected, CAT sequences were not detected in
wild-type-
or mock-infected cells (Fig.
2C, lanes 1 and 2). However, a
single
specific band between 1.8 and 2.1 kb was detected in all
recombinant
viruses, confirming the presence of the CAT gene (Fig.
2C,
lanes
3 to 7). Furthermore, the size of each band was consistent with
the length of the UL112-113 promoter mutation inserted.
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FIG. 2.
Site of recombination in the HCMV genome and Southern
blot analysis of recombinant viruses. (A) Schematic representation of
the site of recombination within the HCMV genome. Shown is the HCMV
Towne strain. White boxes denote the terminal repeat sequences. Black
bars beneath the genome indicate the location of the endogenous
UL112-113 genes and the site of insertion within the region between the
US9 and US12 genes. (B) Expanded map of the region between the US9 and
US12 genes in recombinant HCMV. Where indicated, the direction of the
open reading frame is shown with an arrow. Sizes of fragments expected
to hybridize to the CAT probe in Southern blots are shown above the
map; sizes of fragments expected to hybridize to the genomic probe are
shown below the map. Angled lines between the shaded bars of the
genomic probe indicate that the probe is contiguous. (C) Southern blot
of genomic DNA from mock- and virus-infected cells, using the CAT probe
for detection. Viruses analyzed are indicated above the autoradiogram.
The expected size range of the hybridized DNA fragment is indicated on
the right. Positions of molecular weight markers are indicated on the
left. W.T., wild type. (D) Southern blot of genomic DNA from mock- and
virus-infected cells, using the genomic probe for detection. Viruses
analyzed are indicated above the autoradiogram. The expected size
ranges of the hybridized DNA fragments are indicated on the right.
Positions of molecular weight markers are indicated on the left.
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To test for purity of recombinant viruses and to confirm proper
insertion into the US9/10 locus, genomic DNA was digested
with
EcoRI and
NcoI, which, in wild-type virus, yields
a 4.5-kb
fragment spanning the US9-US12 genes. This 4.5-kb sequence was
also used as a probe for Southern blots. The 4.5-kb fragment was
detected in cells infected with wild-type virus, whereas no signal
was
detected in mock-infected cells (Fig.
2D, lanes 1 and 2).
In
recombinant viruses, an
EcoRI/
NcoI digest gave a
pattern different
from that of wild-type virus due to the presence of
two additional
EcoRI sites within the inserted sequences
(Fig.
2B). Therefore,
the 4.5-kb probe detected two fragments flanking
the insertion
site; a 2.5-kb fragment containing the US9 and
gpt genes, and
a fragment containing the US10-12 genes, the
UL112-113 promoter,
and CAT sequences (Fig.
2D, lanes 3 to 7). The size
of the latter
fragment varied from 3.3 to 3.6 kb, depending on the
promoter
mutation. The pattern shown in Fig.
2D confirmed the site of
insertion
between the US9 and US10 genes. The purity of the
recombinants
was verified by the absence of a 4.5-kb band on longer
exposures
(data not shown).
Analysis of viral protein production in recombinant virus
infection.
The US9/10 region has been shown to accept the
insertion of exogenous DNA without affecting viral growth (11,
14). However, it was important to verify that all constructed
recombinant viruses had normal growth characteristics. To assess the
growth characteristics of the recombinant viruses and to confirm that
the endogenous UL112-113 promoter behaved normally, we analyzed the
kinetics of expression of the endogenous UL112-113 family of proteins
during recombinant virus infection. In a wild-type virus infection, a 43-kDa protein is detected by 8 h after infection; by 48 to
72 h after infection, the 34-, 50-, and 84-kDa proteins are also detected (37). By Western blot analysis, we determined that the pattern of expression of the UL112-113 family of proteins in the
recombinant viruses was similar to that in wild-type Towne virus at
both early and late time points (Fig. 3).
In addition, all recombinant viruses grew to titers similar to that of
wild-type Towne virus (data not shown). These results suggest that
insertion of sequences between the US9 and US10 genes had no effect on
viral growth or endogenous UL112-113 promoter activity.
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FIG. 3.
Western blot analysis of the UL112-113 proteins during
infection with recombinant viruses. Western blot analysis was performed
with total protein isolated from infected cells at 8 (A), 24 (B), 48 (C), and 72 (D) h after infection as described in Materials and
Methods. The recombinant viruses used are indicated above each blot.
Sizes of the UL112-113 proteins are indicated in kilodaltons on the
right of each blot; positions of molecular weight markers are indicated
in kilodaltons on the left of each blot. The band detected just above
66 kD appears to be a cross-reactive protein and has been previously
observed in some experiments (36). The band near 116 kDa is
detected only with recombinant viruses and may represent LacZ expressed
from the human -actin promoter. wt, wild type.
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Analysis of CAT protein and RNA expression from the US9/10 locus in
the recombinant virus v358-CAT.
The recombinant virus designated
v358-CAT contains wild-type UL112-113 promoter sequences from 323 to
+35 (Fig. 4A). These promoter sequences
contain four binding sites for the HCMV transactivator protein IE86 and
one ATF/CREB binding site upstream of the TATA box (1, 15, 23,
24). v358-CAT was used to test the pattern of expression of the
UL112-113 promoter when inserted into the US9/10 locus. CAT assays
performed on lysates harvested at 8, 24, 48, and 72 h after
infection showed low levels of protein at 8 h after infection
followed by an accumulation of higher levels of protein starting at
24 h after infection (Fig. 4B). This was similar to the
accumulation of protein levels of the endogenous UL112-113 family of
proteins at the same times after wild-type virus infection (Fig. 3)
(37). UL112-113 promoter expression from the US9/10 locus
was also examined by primer extension analysis using a primer that
hybridizes to sequences within the CAT gene (Fig. 4C). By using total
RNA isolated at 8, 24, 48, and 72 h after infection, it was
demonstrated that the previously mapped early mRNA start site for the
UL112-113 promoter (28) was also used when the promoter was
inserted in the US9/10 region. Beginning at 48 h after infection,
transcription from the early (+1) start site declined and transcription
initiated from a new start site at 62. These kinetics, including the
switch in transcriptional start sites at late times, mimic that of the
endogenous UL112-113 promoter (28), demonstrating that
insertion of promoter sequences within the US9/10 locus represents a
valid method to study UL112-113 promoter activity in the context of a
viral infection.
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FIG. 4.
Analysis of CAT RNA and protein expression during
infection with v358-CAT recombinant virus. (A) Map of the UL112-113
promoter and CAT gene inserted into v358-CAT. Sequences from 323 to
+35 were linked to the CAT gene and inserted into a recombinant virus
as described in Materials and Methods. Arrows indicate the location and
direction of transcription of RNA from the early start site (+1) and
the late start site (62). Previously identified regulatory regions
are indicated by the shaded boxes. (B) CAT activity detected in lysates
from v358-CAT-infected cells. Protein lysates from infected cells were
harvested at 8, 24, 48, and 72 h after infection with v358-CAT.
CAT activity was determined as described in Materials and Methods and
is represented as percent acetylation per microgram of lysate used in
the reaction. Time points are indicated below the histogram. (C) Primer
extension analysis of total RNA isolated from v358-CAT-infected cells.
Total RNA was isolated from infected cells at 8, 24, 48, and 72 h
after infection, and primer extension analysis was performed as
described in Materials and Methods, using a primer which detects CAT
mRNA. Extension products were separated by denaturing polyacrylamide
gel electrophoresis and subjected to autoradiography. Products were
electrophoresed adjacent to a sequencing ladder (lanes T, G, C, and A)
generated with plasmid p148-CAT and the identical CAT primer to
identify transcriptional start sites. Locations of start sites are
indicated at the right. Time points are indicated below the
autoradiogram. hpi, hours postinfection.
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CAT activity from UL112-113 recombinant viruses.
Previous
transient expression assays have shown that the three IE86 binding
sites between 323 and 113 have very little effect on UL112-113
promoter activity (1, 15, 23, 24). These experiments also
identified the ATF/CREB site between 71 and 66 as the major element
upstream of the TATA box contributing to promoter activity. Therefore,
in determining which UL112-113 promoter sequences are important during
viral infection, we have concentrated on the sequences between 113
and +35, which contain, in addition to the ATF/CREB site and the TATA
box, a weak IE86 binding site (Fig. 1A) (24). The
recombinant virus containing the sequences between 113 and +35 is
designated v148-CAT (Fig. 1B). CAT assays performed with lysates
harvested at 8, 24, 48, and 72 h after infection with v148-CAT
showed kinetics similar to that of v358-CAT (compare Fig.
5 to Fig. 4B). CAT levels at each time
point were about twofold lower in v148-CAT infections compared to
v358-CAT, confirming that the three upstream IE86 binding sites in
combination have only a moderate effect on promoter activity.
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FIG. 5.
Analysis of CAT protein expression during infection with
recombinant viruses containing UL112-113 promoter deletions. Protein
lysates were prepared at 8, 24, 48, and 72 h postinfection (hpi),
and CAT activity was determined as described in Materials and Methods.
Activity is represented as percent acetylation per microgram of lysate
used in the reaction. Solid bars represent the average of two
independent infections; error bars represent the range of the two
values. Promoter deletions contained in the recombinant viruses
analyzed are indicated on the left.
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Our initial analysis also included two recombinant viruses containing
promoter deletions that were previously analyzed in
transient
expression assays (
23). Recombinant virus v119-CAT
contains
sequences from
84 to +35 and is missing all IE86 binding
sites but
maintains the ATF/CREB site and TATA box (referred to
as D in reference
23). Recombinant virus v148(
84-58)-CAT is
deleted
for sequences between
84 and
58 and contains the weak
IE86 binding
site and the TATA box but lacks the ATF/CREB site
(referred to as Del
in reference
23).
In transient assays, it was previously shown that deletion of the weak
IE86 binding site resulted in a twofold drop in promoter
activity
(
23). Analysis of CAT activity derived from v119-CAT
infection showed a similar twofold drop in CAT activity relative
to
v148-CAT when assayed at 8 and 24 h after infection. However,
at
48 and 72 h after infection, there were decreases of 6.8- and
15.8-fold, respectively (Fig.
5). These data suggested that although
sequences containing the IE86 binding site play a modest role
early
infection, those sequences play a greater role in UL112-113
promoter
activity late in infection.
It was also shown by transient assays that deletion of the ATF/CREB
site results in a 20-fold drop in UL112-113 promoter activity
(
23). Analysis of CAT activity derived from
v148(
84-58)-CAT
infection showed a similar dependence on the
ATF/CREB site early
during infection. At 8, 24, and 48 h after
infection, deletion
of the ATF/CREB site resulted in 19.6-, 51.2-, and
68.9-fold decreases
in CAT activity, respectively, relative to
v148-CAT. However,
between 48 and 72 h after infection with
v148(
84-58)-CAT, CAT
levels were stimulated approximately 52.8-fold.
Furthermore, CAT
levels 72 h after infection with
v148(
84-58)-CAT were only twofold
lower than that detected 72 h
after infection with v148-CAT. Although
the ATF/CREB site is a major
regulatory element early in the infection,
these data suggest that this
site plays little if any role at
late times in the infection. Taken
together, these results demonstrate
that separate DNA elements
differentially regulate the UL112-113
promoter at early and late times
in the infection.
Primer extension analysis of UL112-113 recombinant viruses.
Since the ATF/CREB site and sequences containing the weak IE86 binding
site seem to have different effects on promoter activity depending on
the stage of the infection, we sought to determine what role these
sequences played in the initiation of transcription from the early (+1)
and late (62) RNA start sites. To this end, primer extension analysis
was performed on RNA isolated at 8, 24, 48, and 72 h after
infection with v148-CAT, v119-CAT, and v148(84-58)-CAT (Fig.
6). During infection with v148-CAT,
transcription initiation from the +1 site increased up to 24 h
after infection and then declined by 48 and 72 h (Fig. 6A). As
with v358-CAT, a shift in the transcriptional start site to 62 was
first observed at 48 h after infection and increased between 48 and 72 h. The levels of extended product mapping to +1 were
slightly lower with v148-CAT than with v358-CAT. However, the levels
mapping to 62 were almost identical, suggesting that the IE86 binding
sites upstream of 113 have no effect on transcription from the late, 62 mRNA initiation site.
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FIG. 6.
Analysis of CAT RNA expression during infection with
recombinant viruses containing UL112-113 promoter deletions. Primer
extension analysis of total RNA isolated from cells infected with
v148-CAT (A), v119-CAT (B), and v148(84-58)-CAT (C) was performed as
described in the legend to Fig. 4. Promoter deletions contained in the
recombinant viruses analyzed are indicated adjacent to each panel.
Arrows indicate the position of the transcriptional start sites
detected in the assay. Products were electrophoresed adjacent to a
sequencing ladder (lanes T, G, C, and A) generated with the plasmid
p148-CAT and the identical CAT primer to identify transcriptional start
sites. Each panel as well as Fig. 4C was derived from the same
autoradiogram but was cropped for display purposes. hpi, hours
postinfection.
|
|
CAT activity observed during infection with v119-CAT suggested that the
sequences from
113 to
85, containing the IE86 binding
site, had
little effect on promoter activity early during infection
but had a
more dramatic role late. By primer extension analysis
of RNA from
v119-CAT infections, we found that transcription from
the +1 site was
identical to that seen with v148-CAT (Fig.
6B).
However, mRNA
initiation from
62 was completely abolished in
v119-CAT infections.
Since the
62 initiation site is still present
in v119-CAT, these
results suggested that sequences upstream from
62, which included the
IE86 binding site, were important in directing
the initiation of
transcription late in infection.
Primer extension analysis was also performed with RNA isolated from
v148(
84-58)-CAT infections. Deletion of the ATF/CREB
site (which
also deleted the
62 position) inhibited transcription
from the +1
site, providing further evidence for the role of the
ATF/CREB site in
early UL112-113 promoter activity. The deletion
of promoter sequences
from
84 to
58 placed the sequences containing
the IE86 binding site
26 nucleotides closer to the TATA box. In
turn, it was observed that
the initiation site detected at 48
and 72 h after
v148-(
84-58)-CAT infection was shifted 28 nucleotides
downstream of
the original
62 position to the
34 position (Fig.
6C, lanes 11 and
12). Taken together, these data suggest that
the site of transcription
initiation from the UL112-113 promoter
late in infection is determined
not by the sequence of the initiation
site but by upstream sequences,
which contain the IE86 binding
site, in a distance-dependent manner.
Furthermore, since the level
of extended product detected at 48 and
72 h after infection with
v148(
84-58)-CAT was comparable to
that detected after v148-CAT
infection (compare Fig.
6C, lanes 11 and
12 with Fig.
6A, lanes
3 and 4), the ATF/CREB binding site was not
required for late
transcription from the UL112-113 promoter.
Late transcription initiation from the UL112-113 promoter.
The
UL112-113 promoter sequences between 113 and 85, which seem to be
responsible for distance-dependent initiation of transcription late in
infection, contain a weak IE86 binding site. In addition, two A-T-rich
sequences are present within this region (Fig. 1C). To determine which
sequences within 113 to 85 were involved in directing late
transcription initiation, we constructed two recombinant viruses
containing site-directed mutations between 113 and 85 in the
context of v148(84-58)-CAT. In v148(84-58)IICRS-CAT, both
A-T-rich sequences have been deleted and the CRS from the HCMV major IE
promoter has been inserted between 108 and 95 in an attempt to
retain IE86 binding to the promoter. A second virus,
v148(84-58)CRS-CAT, contains the CRS but leaves intact the A-T-rich
sequences between 94 and 85 (Fig. 1C). In v148(84-58)IICRS-CAT infections, CAT levels at all time points tested were comparable to the
levels detected in cells infected with v148(84-58)-CAT (Fig.
7). Thus, the original interpretation was
that the mutations had no effect on late transcription. However, primer
extension analysis of RNA isolated from v148(84-58)IICRS-CAT
infections showed that transcription from the normal late start site
[34 with v148(84-58)-CAT] was abolished, and a new RNA start
site, with identical kinetics, was detected upstream at 140 (Fig.
8). Of particular interest was the
observation that this new start site was located approximately 39 nucleotides upstream from the center of the CRS element, similar to the
distance between the normal late start site and the IE86 binding site
in v148-CAT. In addition, a weaker start site with kinetics similar to
transcription from the +1 early site was detected at 112. Primer
extension analysis of RNA isolated 72 h after infection with
v148(84-58)CRS-CAT showed a pattern similar to that of
v148(84-58)IICRS-CAT, but with low levels of transcripts
also initiating at or near 34.
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FIG. 7.
Analysis of CAT protein expression during infection with
v148(84-58)IICRS-CAT. Protein lysates were prepared at 8, 24, 48, and 72 h after infection with either v148(84-58)-CAT or
v148(84-58)IICRS-CAT, and CAT activity was determined as described
in Materials and Methods. Activity is represented as percent
acetylation per microgram of lysate used in the reaction. Solid bars
represent the average of two independent infections; error bars
represent the range of the two values. Promoter deletions and
site-directed mutations contained in the recombinant viruses analyzed
are indicated on the left. hpi, hours postinfection.
|
|
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FIG. 8.
Analysis of CAT RNA expression during infection with
v148(84-58)-CAT, v148(84-58)CRS-CAT, and v148(84-58)IICRS-CAT.
Primer extension analysis of total RNA isolated from cells infected
with v148(84-58)-CAT (A), v148(84-58)IICRS-CAT (B), and
v148(84-58)CRS-CAT (C) was performed as described in the legend to
Fig. 4 except that only the 72-h time point was analyzed for
v148(84-58)CRS-CAT. Promoter deletions contained in the recombinant
viruses analyzed are indicated adjacent to each panel. Arrows indicate
positions of the transcriptional start sites detected in the assay.
Numbers represent the positions of the nucleotides relative to the
sequence of the promoter in v148-CAT. Each panel was derived from the
same autoradiogram but was cropped for display purposes. hpi, hours
postinfection.
|
|
Thus, replacement of the sequences between
108 and
95 with the CRS
had no effect on the kinetics of late transcription or
on the distance
of the late start site from the center of the
element between
108 and
95. However, when the CRS was inserted,
the late start site was now
positioned approximately 39 nucleotides
upstream of the element rather
than downstream. Taken together,
these data suggest that the sequences
between
108 and
95 play
a role in directing late transcription from
the UL112-113 promoter,
in a distance-dependent and possibly
orientation-dependent manner.
| |
DISCUSSION |
The goal of this study was to more accurately define the roles of
specific sequence elements within the HCMV UL112-113 promoter during
infection. The success of the recombinant virus approach depended on
the ability of the UL112-113 promoter inserted into a different region
of the genome to function similarly to the endogenous promoter. We
found that when inserted between the US9 and US10 genes, the UL112-113
promoter showed identical kinetics of RNA expression as the endogenous
promoter located in the UL region. As with the endogenous promoter, the
inserted UL112-113 promoter was active both early and late in
infection. In particular, a shift in the RNA start site late in
infection was also observed from the inserted UL112-113 promoter. Taken
together, our data indicated that expression of the UL112-113 promoter
was accurately represented when located at an alternate position in the
genome and in the opposite orientation relative to the endogenous
promoter. Thus, by inserting the UL112-113 promoter-CAT sequences into
the HCMV genome, we were able to determine which promoter elements were
functional at various times after infection.
UL112-113 promoter activity late in infection.
The results
presented here from early time points (8 and 24 h) during
recombinant virus infection are in agreement with data previously
obtained from transient expression analysis (1, 15, 23, 24).
Namely, for the UL112-113 promoter, the ATF/CREB site played a major
role early in infection, whereas the sequences containing the IE86
binding site (113 to 85) played an accessory role. However, the
most intriguing finding in this study was that late in infection, the
relative importance of the ATF/CREB site and the sequences containing
the IE86 binding site was reversed. By 72 h after infection, the
ATF/CREB site was no longer functional in transcriptional activation,
whereas the sequences between 113 to 85 were required for the
switch to the late RNA start site and wild-type levels of late
transcription. This phenomenon was not detected by transient expression
analysis and demonstrates the importance of using recombinant viruses
to accurately determine temporal regulation of viral promoters during
infection.
Two experiments indicated that the ATF/CREB site was no longer
functional late in infection. First, infection with v148(
84-58)-CAT,
which is deleted for the ATF/CREB site, and v148-CAT, which contains
the ATF/CREB site, resulted in a similar induction of CAT activity
by
72 h (Fig.
5). Second, during infection with a recombinant
virus
containing only the ATF/CREB site and TATA box (v119-CAT),
CAT levels
steadily declined late in infection despite the increase
in viral
template DNA. Furthermore, v119-CAT showed CAT levels
at 72 h
after infection similar to those of a virus containing
only the TATA
box (data not shown). Since CREB is the major protein
that binds to the
UL112-113 ATF/CREB site in uninfected cells
(
23), our data
suggest that CREB activity is downregulated at
late times in the
infection. Although it has been known for many
years that some early
HCMV promoters are downregulated late in
infection (for a review, see
reference
20), this study provides
the first
evidence to suggest that one mechanism of early promoter
shutoff is due
to down regulation of specific host transcription
factor activity as
the infection proceeds.
Although CREB binds to the UL112-113 ATF/CREB site in uninfected cell
extracts, it is not known whether CREB still binds to
this promoter
late in the infection. The binding activity of another
member of the
ATF/CREB family, ATF-1, is induced at late times
during infection
(
11). However, the UL112-113 ATF/CREB site
binds little if
any ATF-1 in uninfected cells (
23), and it is
not known if
ATF-1 can bind to the UL112-113 ATF/CREB site late
in infection. If
ATF-1 can bind to the UL112-113 ATF/CREB site
late in infection, our
data suggest that this binding cannot lead
to transcriptional
activation since the UL112-113 ATF/CREB site
was not functional in late
transcription.
There are several possible mechanisms for the downregulation of CREB
activity during infection, including, but not limited
to, degradation,
dephosphorylation, or alternative modification
of CREB. CREB activity
is normally regulated through phosphorylation
on Ser-133 (
6)
which is required for interaction with the CREB
binding protein
(
4). Preliminary results from our laboratory
indicate that
CREB protein levels remain constant throughout infection
(
19). However, it appears that Ser-133 becomes
dephosphorylated
as the infection proceeds and that there are
additional modifications
to CREB. Thus, it is possible that HCMV
encodes or modifies functions
to regulate host transcription factor
activity so that certain
viral genes are expressed at specific times
during the infection.
Studies are in progress to address these
questions.
Although the sequences between
113 and
85, which contain a weak
IE86 binding site, are dispensable for early transcriptional
activity,
results from experiments with two recombinant viruses
suggested that
these sequences are required for normal levels
of late transcription as
well as the change in RNA start site
observed at 48 and 72 h after
infection. First, deletion of the
sequences between
113 and
85 in
v119-CAT abolished transcription
initiation from the
62 position late
in infection. Second, deletion
of the sequences between
84 to
58 in
v148(
84-58)-CAT had no
effect on the levels of late transcription,
but the late RNA initiation
site was moved 28 bp downstream to
34, a
distance similar to
the number of deleted nucleotides between
84 and
58 (Fig.
6).
This putative distance-dependent late transcription
initiation
seems to be unique to the sequences around the weak IE86
site,
since no transcription initiation is detected near the upstream
IE86 binding sites (Fig.
4C). However, at present we do not know
whether the three upstream IE86 sites can contribute to transcription
initiation either late in infection in the absence of the sequences
containing the weak IE86 binding site or early in infection in
the
absence of the ATF/CREB site.
Since the sequences from
113 to
85 are protected by IE86 in a DNase
I footprint, it is possible that IE86 binding to this
sequence plays a
role in late transcription initiation from the
UL112-113 promoter.
Alternatively, there are two A-T-rich sequences
within that region
which could behave as TATA-like sequences to
direct late transcription
in a distance dependent manner. To distinguish
between these
possibilities, we constructed two recombinant viruses
that contained
substitution mutations between
113 and
85, v148(
84-58)CRS-CAT
and v148(
84-58)IICRS-CAT. Although the sequences from
113 to
85
are protected by IE86 in a DNase I footprint, this sequence
diverges
somewhat from the consensus IE86 binding site. Based
on footprint
analyses, a consensus IE86 binding site consists
of an A-T-rich
10-nucleotide sequence bounded by CG dinucleotides
(
1,
16,
24). The sequence between
113 and
86 contains
a CG with A-T
rich sequences on either side but lacks a complementary
CG dinucleotide
(Fig.
1). The best approximation of the IE86 binding
site within the
113 to
84 sequence, based on the DNase I protection
pattern
(
24), would be nucleotides
108 to
95. Therefore, we
replaced that sequence with the CRS in v148(
84-58)CRS-CAT to
determine if the IE86 binding site was involved in late transcription.
We also constructed another virus, v148(
84-58)IICRS-CAT, which
included mutation of the TATA-like sequences from
88 to
84 in
addition to the substituted CRS.
The results of the primer extension analyses on all recombinant viruses
are summarized in Fig.
9. Substitution of
the sequences
between
108 and
85 resulted in several interesting
observations.
First, transcription from the late RNA start site at
34
was abolished
in v148(
84-58)IICRS-CAT, suggesting that the sequences
from
108
to
85 were involved in directing late transcription
initiation
at the downstream site. We also noted that there was a very
low
level of steady-state RNA initiating near
34 in
v148(
84-58)CRS-CAT
infection. One interpretation of these data is
that the TATA-like
sequence between
88 and
84 may play a role in
determining the
site of late transcription initiation and that the
upstream sequences
between
108 to
95 are important for high-level
expression. However,
because close inspection of the gels suggests that
this RNA may
actually be initiating at
33, it is possible that the
substituted
sequences have activated a weak cryptic site for initiation
at
late times. Nevertheless, it appears that the wild-type sequences
containing the weak IE86 binding site between
108 and
95 are
involved in downstream late transcription initiation.
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FIG. 9.
Summary of RNA start sites from recombinant viruses and
schematic representation of promoter mutations used in this study.
Names of the viruses containing the promoters are indicated at the
left. Major early (E) RNA start sites are denoted by open arrowheads,
whereas major late (L) RNA start sites are denoted by closed
arrowheads. Minor RNA start sites are shown as dashed arrows. Sequence
elements are as described in the legend to Fig. 1. Numbers represent
the positions of the nucleotides relative to the sequence of the
promoter in v148-CAT.
|
|
One of the most interesting observations from the primer extension
analysis of v148(
84-58)CRS-CAT and v148(
84-58)IICRS-CAT
infections was the emergence of two new RNA start sites upstream
of the
inserted CRS. A weak start site with early kinetics was
detected
initiating from
112. However, since this site is observed
only in
v148(
84-58)IICRS-CAT, it is likely the result of mutation
of the
sequences between
94 and
85. The strongest of the two
new sites
initiated at
140 and displayed late kinetics. Thus,
late
transcription was abolished from a position downstream of
the IE86
binding site and instead initiated at a novel position
upstream.
Interestingly, the novel late RNA start site initiated
within the
polylinker sequence which had been inserted as a result
of cloning the
UL112-113 promoter into the transfer vector used
for recombinant virus
construction. Since this novel late RNA
start site was detected during
infection with both v148(
84-58)CRS-CAT
and v148(
84-58)IICRS-CAT,
insertion of the CRS was responsible
for the appearance of this site.
It is interesting that the distance
from the novel late start site
(
140) to the center of the inserted
CRS (between nucleotides and
102 and
101) is almost identical
to the distance from the center of
the putative weak IE86 binding
site (between nucleotides and
102 and
101) to the wild-type
late start site (
62) detected in v148-CAT
infection. This observation
raises the possibility that the orientation
of the CRS, and of
the weak IE86 binding site within the wild-type
UL112-113 promoter,
determines the positioning of the late
transcriptional start site.
Since IE86 binds to the minor groove of the
DNA (
17), the orientation
of the IE86 binding site relative
to other surrounding sequences
may result in certain structural effects
on IE86 binding that
determine the position of late transcription
initiation. Alternatively,
unidentified sequences within the CRS, and
within the UL112-113
promoter sequences between
108 and
95, may be
involved in orientation-dependent,
late transcription initiation
independent of IE86 binding. At
present, we also cannot rule out the
possibility that the mutations
cause activation of an upstream cryptic
promoter which results
in initiation of transcription at position
140. Further experiments
are under way to determine the precise
sequences required, the
dependence on orientation and distance, and
whether IE86 binding
to these sequences is essential.
UL112-113 promoter activity early in infection.
Analysis of
CAT activity and mRNA levels at 8 and 24 h after infection with
v148(84-58)-CAT, which is deleted for the ATF/CREB site, suggested
that the ATF/CREB site is required for high levels of promoter activity
early in infection, whereas the sequences containing the IE86 binding
site are less important. Since deletion of the ATF/CREB site positioned
the IE86 binding site closer to the TATA box, one can argue that the
IE86 site is no longer functional due to the change in its position.
However, in transient expression assays, site-directed mutation of the
ATF/CREB site without altering the position of the IE86 binding site
showed that the IE86 site could not compensate for the loss of the
ATF/CREB site (23). Since our results suggest that UL112-113
promoter activity in transient expression assays mimics that of early
time points during infection, we expect that the IE86 site in its
normal location also would not compensate for the loss of the ATF/CREB
site early in infection.
Since the ATF/CREB site is functional only early during infection and
since the host transcription factor CREB binds to this
site within the
UL112-113 promoter, HCMV, like many viruses, employs
the strategy of
utilizing cellular transcription factors in the
initial phases of the
infection. However, only weak expression
from the UL112-113 promoter is
observed when viral protein synthesis
is inhibited (
27),
suggesting that other viral proteins, such
as IE86, are required for
maximum levels of transcription. Our
results also suggested that the
sequences containing the weak
IE86 binding site played only a modest
role early in infection.
Similarly, in transient expression assays,
deletion of the weak
IE86 binding site reduced UL112-113 promoter
activity only about
twofold (
23). However, in the transient
expression experiments
the IE86 protein is required for promoter
activity even in the
absence of an IE86 binding site on the promoter.
Thus, IE86 may
function through protein-protein contacts without the
requirement
for DNA binding, or at least without the need for a
consensus
IE86 binding site. Indeed, IE86 can interact with the CREB
binding
protein (CBP) and weakly with a truncated form of CREB,
CREB
(
15,
23). Since IE86 is expressed in the recombinant virus
infections, these studies do not allow us to distinguish the role
of
the IE86 protein at the promoter early in infection. We can
only
conclude that the sequences containing the weak IE86 binding
site are
not essential for early UL112-113 promoter activity.
The results presented here suggest that for specific promoters there
are different mechanisms governing early and late viral
transcription.
It is likely that many early promoters use existing
cellular
transcription factors, as well as virus-encoded factors,
to enhance
transcription under low-template conditions prior to
viral DNA
replication. However, as the infection proceeds, certain
cellular
factors may be either downregulated or upregulated to
alter the
expression pattern of specific viral genes. Although
there is an
increase in viral DNA template late in infection due
to DNA
replication, transcription from the +1 position in the
UL112-113
promoter decreases. The mechanism governing this downregulation
of
transcription from one site and upregulation from a different
site late
in infection is unclear. Further analysis of other early
and late HCMV
promoters is needed to fully understand the regulation
of viral gene
expression during infection.
| |
ACKNOWLEDGMENTS |
We thank Ruth Schwartz and Ed Mocarski for plasmids used in this
study. We also thank Roopashree Dwarakanath, Elizabeth Fortunato, Anita
McElroy, Chris Morello, and Bryan Salvant for helpful discussions and
critical reviews of the manuscript.
This investigation was supported by NIH grant CA 34729 (D.H.S.) and NIH
training grant AI-07384 (S.M.R.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biology, 0357, University of California, San Diego, 9500 Gilman Dr., La
Jolla, CA 92093-0357. Phone: (619) 534-9737. Fax: (619) 534-6083. E-mail: dspector{at}ucsd.edu.
| |
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J Virol, April 1998, p. 2697-2707, Vol. 72, No. 4
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
