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Previous Article | Next Article 
Journal of Virology, April 2001, p. 3391-3403, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3391-3403.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Efficient Activation of Viral Genomes by Levels of
Herpes Simplex Virus ICP0 Insufficient To Affect Cellular Gene
Expression or Cell Survival
William E.
Hobbs,1
Douglas E.
Brough,2
Imre
Kovesdi,2 and
Neal A.
DeLuca1,*
Department of Molecular Genetics and
Biochemistry, University of Pittsburgh School of Medicine, Pittsburgh,
Pennsylvania 15261,1 and GenVec, Inc.,
Gaithersburg, Maryland 208782
Received 3 November 2000/Accepted 5 January 2001
 |
ABSTRACT |
Herpes simplex virus (HSV) ICP0 can effectively activate gene
expression from otherwise silent promoters contained on persisting viral genomes. However, the expression of high levels of ICP0, as from
ICP4
HSV type 1 (HSV-1) vectors, results in marked
toxicity. We have analyzed the results of ICP0 expressed from an
E1 E4 adenovirus vector (AdS.11E4ICP0) in
which ICP0 expression is controlled from the endogenous adenoviral E4
promoter. In this system, the expression level of ICP0 was reduced more
than 1,000-fold relative to the level of expression from HSV-1 vectors.
This low level of ICP0 did not affect cellular division or greatly
perturb cellular metabolism as assessed by gene expression array
analysis comparing the effects of HSV and adenovirus vector strains.
However, this amount of ICP0 was sufficient to quantitatively destroy
ND10 structures as measured by promyelocytic leukemia
immunofluorescence. The levels of adenovirus-expressed ICP0 were
sufficient to activate quiescent viral genomes in trans and
promote persistent transgene expression in cis. Moreover,
infection of complementing cells with AdS.11E4ICP0 promoted viral
growth and resulted in a 20-fold increase in the plaquing efficiency of
d109, a virus defective for all five immediate-early genes.
Thus, the low level expression of ICP0 from the E1
E4 adenovirus vector may increase the utility of
adenovirus vectors and also provides a means to efficiently quantify
and possibly propagate HSV vectors defective in ICP0. Importantly, the
results demonstrate that the activation function of ICP0 may not result from changes in cellular gene expression, but possibly as a direct consequence of an enzymatic function inherent to the protein that may
involve its action at ND10 resulting in the preferential activation of
viral genomes.
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INTRODUCTION |
During productive herpes simplex
virus type 1 (HSV-1) infection, three classes of viral genes are
temporally expressed in the following order: immediate-early (IE),
early (E), and late (L) genes (24, 25). Four of the five
IE genes (ICP0, ICP4, ICP22, and ICP27) encode the main regulatory
functions for virus gene expression (42, 45, 56). One of
these proteins, ICP0, is not essential for virus growth in vitro;
however, ICP0-defective viruses grow very slowly and are considerably
impaired at low multiplicities of infection (47, 54). ICP0
mutants also reactivate very poorly from latency in mice and rabbit
models (3, 7, 11, 21, 34, 46), suggesting a role for ICP0
in reactivation from latency.
The mechanism by which ICP0 facilitates viral growth and the
reactivation from latency is not well understood. Several groups have
shown that ICP0 will nonspecifically transactivate reporter genes in
transient assays (12, 19, 39, 44). Mutants of ICP0 that
are defective for this activation function are also defective for
promoting viral growth and reactivation from latency (3),
suggesting that the ability to activate gene expression reflects the
requirement for ICP0 in viral infection. It has been shown that HSV
gene expression becomes repressed in cells in the absence of viral IE
gene expression (43, 48) and that ICP0 is sufficient to
reactivate gene expression from quiescently persisting HSV genomes in
cells (22, 48, 59). Therefore, it is believed that
repression is counteracted by the action of ICP0. ICP0 may counteract
repression by stimulating the degradation of a number of cellular
proteins via the ubiquitin-proteasome pathway (15, 17).
However, ICP0 has been proposed to interact with a number of cellular
factors representative of a variety of cellular pathways that are
potentially capable of contributing to its properties. These include
components of cellular transcriptional (33), translational (29), protein degradation (13, 14, 15, 16),
and cell cycle control (14, 23, 30, 35) pathways.
Given the plethora of potential interactions between ICP0 and critical
cellular functions it is reasonable to assume that ICP0 would have
effects on host cell metabolism and survival. Indeed, several studies
have documented the deleterious effects of ICP0 on cellular metabolism,
particularly in dividing cells (14, 23, 50, 58). The
observed effects of ICP0 on aspects of cellular metabolism may be a
direct reflection of the mechanism by which ICP0 functions in viral
infection, or they may be a simple by product of ICP0 action, having
little to do with the mechanism by which ICP0 activates gene
expression. Alternatively, such effects may be the consequence of
overproduction of ICP0.
In the present study we investigated the quantitative requirement for
ICP0 with respect to the activation of quiescent genomes, the
activation of viral gene expression, and the ability to complement ICP0
mutants. We have found it possible to maintain ICP0 gene activation
function while reducing or eliminating its toxic properties by
expressing ICP0 from an E1 E4 adenovirus in
which ICP0 expression is controlled from the endogenous adenovirus E4
promoter. The reduced amount of ICP0 expressed from AdS.11E4(ICP0) was
sufficient to activate quiescent viral genomes in trans and
promote persistent transgene expression in cis. Gene expression array experiments demonstrated that expression of low levels
of ICP0 from AdS.11E4(ICP0) did not greatly affect the expression of
cellular genes relative to an HSV mutant where IE gene expression is
limited to ICP0. However, the ICP0 expressed from the adenoviral
backbone was sufficient to disrupt ND10 structures, which are punctate
nuclear domains of unknown function that are modified during HSV
infection (37). Moreover, infection with AdS.11E4(ICP0)
complemented growth of ICP0-deficient HSV-1, suggesting that the low
level of ICP0 expression from the E1 E4
adenovirus vector may provide a means to efficiently quantify and
possibly propagate such HSV-1 IE mutants. Importantly, the results
demonstrate that the activation function of ICP0 may result not from
changes in cellular gene expression but possibly as a direct
consequence of an enzymatic function inherent to the protein.
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MATERIALS AND METHODS |
Cells and viruses.
Human embryonic lung (HEL) fibroblasts
and Vero cells were obtained from the American Type Culture Collection
and maintained in Dulbecco's modified Eagle medium (DMEM)-10% fetal
bovine serum (FBS) as previously described. HSV-1 IE complementing cell
line FO6 is a Vero-derived cell line previously described
(50). Adenovirus mutants AdS.10, AdS.11D, and
AdS.11E4(ICP0) are diagrammed in Fig. 1
and were constructed at GenVec, Inc., Gaithersburg, Md. Details of
their construction will be published elsewhere. The wild-type (wt)
strain of HSV-1 used in these experiments is strain KOS. HSV-1 IE
mutant viruses d99, d105, d106, and
d109 have been previously described (48), and
their genome structures are also shown in Fig. 1.
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FIG. 1.
Adenovirus and HSV-1 mutant virus structures. (A)
Adenovirus constructs compared to wild-type Ad5 structure (top) with
respect to E1, E3, and E4 regions. All mutants contain the HCMVIEp-SEAP
transgene inserted in the E1 locus and are also deficient for E3
function. Shown also is the insertion of a nonsense spacer or HSV-1
ICP0 in the E4 locus of viruses AdS.11D and AdS.11E4(ICP0),
respectively. (B) The HSV-1 viral genome (top) demonstrating the locus
of the 5 IE genes (arrows) relative to the unique long
(UL), unique short (US), and repeat sequences
(boxes). IE deletion mutants have been previously reported
(31).
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Microscopy and immunofluorescence.
Confluent monolayers of
HEL cells were infected with d109 (multiplicity of infection
[MOI] = 10) and then superinfected 24 h later with either
d105 or Ad11S.E4(ICP0) at the indicated MOI. Cells were
visualized by fluorescence microscopy using a Nikon Diaphot 300 with
appropriate filters for green fluorescent protein (GFP) detection.
For immunofluorescence studies, infected and uninfected cells were
prepared on circular coverslips. The cells were infected with
d109 (MOI = 10) and superinfected 24 h later with
either d105, AdS.10, AdS.11D, or AdS.11E4(ICP0). At 24 h postsuperinfection, cells were fixed in 4% paraformaldehyde and
permeabilized with 0.2% Triton X-100 and stained for promyelocytic
leukemia (PML) detection as previously described (48).
Anti-PML antibody (Santa Cruz Biotechnology) was used at a dilution of
1:30. The stained antigens were visualized with the appropriate cubes
for fluorescence imaging in conjunction with a Nikon FXA photomicroscope.
Western blot analysis.
HEL cells were infected (10 PFU of
HSV-1 or 1,000 focus-forming units (FFU) of adenovirus per cell) with
the indicated virus. At the indicated times postinfection, cells were
harvested in a Triton X-100-containing lysis buffer as previously
described, and equal amounts of total protein were separated by sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as
previously described (23). Proteins were transferred to
polyvinylidene difluoride membranes and probed with anti-ICP0 antibody
(Goodwin Institute for Cancer Research) or anti-GFP antibody (CLONTECH) and detected as previously described (23).
Cell proliferation assay.
Cellular proliferation following
infection was assessed as previously described (23).
Briefly, 105 HEL cells were seeded in duplicate on
35-mm-diameter dishes. Cells were then infected or mock infected with
10 PFU/cell (HSV-1) or 1,000 FFU/cell (adenovirus). Cells were
harvested by trypsinization at the indicated times postinfection and
counted on a hemocytometer.
Microarray analysis.
HEL cells were infected as described
above and total RNA was isolated and poly(A)+ mRNA was
selected as previously described (23). Microarray analysis
was conducted by Incyte Pharmaceuticals on Human UniGEM V and data was
analyzed using GEMTools software.
35S metabolic labeling.
HEL cells were infected
or mock infected with d109 (MOI = 20) and maintained at
34°C for 7 days in DMEM containing 2% FBS. Cells were then
superinfected with d105, AdS.11D, or AdS.11E4(ICP0) at the
highest MOI shown in Fig. 2. Cells were
pulsed with [35S]met-[35S]cys 12 h
postsuperinfection for 12 h, at which time cell lysates were
harvested as described above and separated by SDS-PAGE and protein
profiles were visualized by autoradiography.
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FIG. 2.
Transactivation of quiescent viral genes. The ability of
ICP0 expressed from either d105 or from AdS.11E4(ICP0) to
transactivate the otherwise silent HCMVIEp-GFP transgene encoded by
d109 was assayed at increasing MOIs Confluent monolayers of
HEL cells were infected with d109 (MOI = 10) and then
superinfected 24 h later with either d105 or
Ad11S.E4(ICP0) at the indicated MOI. Cells were visualized by
fluorescence microscopy 48 h later. d109-infected cells that
were not superinfected are also shown (mock). The single fluorescent
cell in this field represents a rare event that was not seen in many
other fields of d109-infected HEL cells.
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Complementation of virus growth, plaquing efficiency, and virus
yield.
HEL cells were infected with d109 (MOI = 20) and maintained at 34°C for 7 days in DMEM supplemented with 2%
FBS. Cells were then infected with d99 in combination with
either d105, AdS.11D, or Ad.S11E4(ICP0) as indicated.
Supernatants were collected at the indicated times postinfection and
d99 titer was determined by plating on Vero cells. Plating
on FO6 cells and counting only small GFP+ plaques
approximated d109 titers. For determination of plaquing efficiency, FO6 cells were infected with AdS.11E4(ICP0) at increasing particle/cell ratios. Twenty-four hours later, the cells were infected
with d109 and the numbers of resulting plaques were counted. To determine virus yield, HEL cells were infected with d109
(MOI = 0.001) 24 h postinfection with AdS.11E4(ICP0), and
supernatants were harvested on days 1, 2, 3, and 4, and the resulting
virus yield determined by titration on AdS.11E4(ICP0) infected FO6 cells.
SEAP expression in HEL cells.
HEL cell monolayers were
infected at 1,000 PFU/cell with AdS.10, AdS11.D, or AdS.11E4(ICP0). The
levels of transgene expression were monitored every three days for
secretory alkaline phosphatase (SEAP) activity in the medium after
complete medium change. The medium was aliquoted and stored at
80°C. SEAP expression levels were detected by chemiluminescence
using Phospha-Light (Tropix). SEAP activity is expressed as relative
light units in 2 µl of medium.
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RESULTS |
AdS11E4(ICP0) can activate expression from silent promoters on
quiescent HSV-1 genomes.
To assess the general activity of ICP0
expressed from an E1 E3 E4
adenovirus vector, we first assessed the ability of AdS.11E4(ICP0) to
transactivate gene expression from promoters contained on quiescent HSV-1 genomes. The virus d109 (Fig. 1) is deleted for all 5 HSV-1 IE functions and thus is replication incompetent and
transcriptionally silent following infection of noncomplementing cells
(48). Samaniego et al. (48) have shown that
d109 genomes persist in a quiescent state in the nucleus of
infected cells for extended periods of time without any detectable
cytotoxic effect. d109 contains an HCMVIEp-GFP transgene
cassette that is also efficiently repressed by the host cell following
infection (48) such that GFP expression is undetectable in
>99% of infected HEL cells. Expression of ICP0 following
superinfection by an HSV-1 IE mutant virus such as d105 (Fig. 1), which is defective for the expression of all the IE proteins
except ICP0, can activate expression from this otherwise silent
HCMVIEp-GFP transgene encoded by d109. Thus, as a marker of
ICP0 activity when expressed from AdS.11E4(ICP0), we compared the
induction of GFP expression from d109 as a function of
d105 or AdS.11E4(ICP0) at different MOI (Fig. 2).
Expression of ICP0 from AdS.11E4(ICP0) was able to induce GFP
expression from resident d109 genomes. As with
d105, infection with increasing MOI of AdS.11E4(ICP0)
resulted in a dose response with respect to the activation of quiescent
d109 genomes as shown by the increased number of
GFP+ cells at an increasing MOI. The control
E1 E3 E4 adenovirus AdS.11D
failed to induce GFP expression (data not shown) (see Fig. 6),
indicating that the effect was due to ICP0 expression. While infection
with d105 was capable of transactivating d109
genomes at a low MOI, a relatively higher number of infectious units
(approximately 1,000-fold higher) of AdS.11E4(ICP0) was necessary for a
similar response.
HSV mutants defective for ICP4 function express dramatically reduced
levels of early transcripts and protein; however, they express
significant levels of ICP6. ICP6 expression from such mutants is
significantly reduced if ICP0 is additionally inactivated, implying
that ICP6 expression is enhanced by ICP0 (50). Therefore, we examined the ability of ICP0 expressed from AdS.11E4(ICP0) to
activate ICP6 expression from resident d109 genomes, and
compared this to the expression of ICP6 from HSV d105
genomes (Fig. 3). As ICP0 has been shown
to activate ICP6 expression (20), it is of note that
AdS.11E4(ICP0) also induced expression of ICP6 from resident
d109 genomes. This indicates that transactivation by ICP0
expressed from AdS.11E4(ICP0) was not limited to transgenes controlled
by the HCMVIE promoter. Also visible in Fig. 3 are ICP0 expressed from
d105, SEAP from the adenovirus strains and GFP from
d109 when superinfected with an ICP0-expressing HSV or adenovirus. The ICP0 expressed from AdS.11E4(ICP0) is not
detectable by this analysis.
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FIG. 3.
Synthesis of viral and cellular proteins. HEL cells were
infected or mock infected with d109 (MOI = 20) and
maintained at 34°C for 7 days in DMEM containing 2% FBS. Cells were
then superinfected with d105, AdS.11D, or AdS.11E4(ICP0) at
the highest MOI shown in Fig. 2. Cells were labeled with
[35S]met-[35S]cys 12 h
postsuperinfection for 12 h, at which time cell lysates were
harvested and separated by SDS-PAGE and protein profiles were
visualized by autoradiography. Virally encoded proteins ICP6, ICP0,
SEAP, and GFP are indicated (arrows). ICP6 is encoded only by HSV-1
vectors d109 and d105, whereas ICP0 is
encoded by both d105 and AdS.11E4(ICP0). SEAP is
contained only on the adenoviral vectors while GFP is encoded only by
the HSV-1 vector d109.
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Complementation of ICP0-deficient virus and reactivation of
quiescent HSV-1 genomes.
Given that expression of ICP0 from
AdS.11E4(ICP0) activated expression of endogenous promoters on
quiescent HSV-1 genomes, it was of interest to investigate whether such
delivery of ICP0 was sufficient with respect to supporting HSV-1
replication. HSV-1 mutants deficient for ICP0 function are replication
competent but replicate to levels several logs less than those of wt
viruses. HEL cells were first infected with d109 and allowed
to incubate for 1 week. The cultures were then superinfected with the
indicated viruses and at various times postinfection were assayed for
virus yield. As expected, d99 grew, albeit poorly, on
d109-infected HEL cells (Fig.
4A), but was not able to reactivate
quiescent d109 (Fig. 4B). Both d105 and
AdS.11E4(ICP0) were able to complement the growth of d99
(Fig. 4A) and reactivate quiescent d109 genomes (Fig. 4B).
AdS.11D was not able to complement d99 nor reactivate quiescent d109 genomes.
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FIG. 4.
Complementation of ICP0-deficient virus and reactivation
of quiescent HSV genomes. HEL cells were infected with d109
(MOI = 20) and maintained at 34°C for 7 days in DMEM
supplemented with 2% FBS. Cells were then infected with d99
in combination with either d105, AdS.11D, or Ad.S11E4(ICP0)
as indicated. Supernatants were collected at the indicated times
postinfection, and the d99 titer was determined by
plating on Vero cells (A). d109 titers were
approximated by plating harvested supernatants on FO6 cells and
counting only small GFP+ plaques (B).
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AdS.11E4(ICP0) increases d109 plaquing efficiency and
virus yield.
Cell culture systems to efficiently propagate and
quantitate HSV-1 IE mutant viruses have been designed to complement
deleted viral functions in trans by stably transfecting the
complementing viral genes into the cellular genome (8, 9, 49,
50). However, growth of HSV-1 with multiple IE deletions on
these complementing cell lines typically produces viral stocks with
lower titers than the wild-type virus. Given the role of ICP0 in
supporting viral gene expression and replication and the ability of
ICP0 expressed from AdS.11E4(ICP0) to complement replication of ICP0
deficient HSV-1, we were interested in whether AdS.11E4(ICP0) may be
useful in propagating and/or quantitating HSV-1 IE mutant viruses.
Infection of the ICP4, ICP27, and ICP0 complementing cell line FO6
(49) with AdS.11E4(ICP0) enhanced the plaquing efficiency
of d109 (Fig. 5). This is
illustrated by the increased number of plaques obtained as a function
of AdS.11E4(ICP0) (Fig. 5A). The control E1
E4 adenovirus AdS.11D failed to exhibit this effect (data
not shown). Consistent with this result, AdS.11E4(ICP0)
enhanced d109 virus growth rate on Vero-derived
complementing cell line FO6 as shown by the increased rate of
production of d109 progeny virus in Fig. 5B.
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FIG. 5.
AdS.11E4(ICP0) increases d109 plaquing
efficiency and virus yield. (A) FO6 cells were infected with
AdS.11E4(ICP0) at increasing particle/cell ratios as indicated. After
24 h, the infected monolayers were used to plaque a stock of
d109. Four days later the plaques were counted, and the
resulting titer of the stock is represented as a function of
AdS.11E4(ICP0). The asterisk denotes that, with more than 5.7 × 102 particles/cell (approximately 11 FFU/cell), FO6 cells
failed to survive 24 h and the monolayer was destroyed prior to
infection with d109. (B) FO6 cells were infected with
1.9 × 102 particles/cell AdS.11E4(ICP0) or
AdS.11D. After 24 h, the cells were infected with d109
(MOI = 0.001) and supernatants were harvested on day 1, 2, 3, and
4, and the resulting virus yield was determined by titering on
ÁdS.11E4(ICP0)-infected FO6 cells.
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Interestingly, Vero cells exhibited marked sensitivity to adenovirus
particles compared to HEL cells. As shown in Fig. 5A, infection with
more than 5.7 × 102 particles/cell (approximately 11 FFU/cell) resulted in rapid cell death. This effect was not limited to
FO6 cells, as Vero cells were also sensitive to equivalent
AdS.11E4(ICP0) particles (data not shown). Infection with the control
E1 E4 adenovirus AdS.11D also resulted in
death of Vero and FO6 cells (data not shown), supporting the hypothesis
that this toxicity arises as a function of the adenovirus particle.
This is in marked contrast to the sensitivity of HEL cells shown in
Fig. 2, which tolerated approximately 100-fold more virus per cell. The
adenoviral penton has been shown to bind integrins
v
3 and v5
during virion internalization (2, 57). This has the
capacity to be toxic to adherent cells by disrupting normal integrin
interactions with the extracellular matrix, thereby promoting cell
detachment (18, 41). Thus, various cell types most likely
exhibit various sensitivities to the adenoviral particle depending on
their dependence on v3 and
v5 for attachment. It may be expected
that differences in the cellular adhesion molecules utilized by
different cell types may result in differences in sensitivity to
adenoviral particles in vivo as well.
Kinetics of ICP0 expression from AdS.11E4(ICP0) and effect on
transgene expression.
In the absence of ICP4 function, the
expression of undeleted IE genes from HSV-1 IE mutant viruses is
increased relative to wt levels. Thus, the effects and cytotoxic
properties of such viruses may be related to effects that arise as a
consequence of prolonged exposure to high levels of IE protein
activity. It was thus of interest to investigate the level of ICP0
expressed from AdS.11E4(ICP0), where ICP0 expression is controlled from the adenovirus E4 promoter. We analyzed ICP0 expression from
d105 or AdS.11E4(ICP0) and induction of
d109-encoded HCMVIEp-GFP following infection of
d109 infected HEL cells at the highest MOI shown in Fig. 2.
ICP0 expression was easily detectable by Western blot analysis within 6 hpi following d105 infection (Fig.
6A). Expression of ICP0 from
AdS.11E4(ICP0), however, was not detectable until 12 hpi, and then only
minimally so by loading 10-fold excess protein in each lane compared to
d105 lanes. While ICP0 expression continued to increase
throughout the 48 h assayed following d105 infection, ICP0 expressed from AdS.11E4(ICP0) reached a maximal level by 24 hpi
that was maintained through 48 hpi. By serial dilutions of
d105-infected cell lysates we determined that
AdS.11E4(ICP0)-infected cells expressed >1,000-fold less ICP0 than
d105-infected cells (Fig. 6C). Using a similar dilution
scheme, we also assessed the relative level of GFP induction by these
two routes of ICP0 expression. The expression of ICP0 from
AdS.11E4(ICP0) resulted in an approximately 500-fold induction of GFP
compared to baseline, which was only approximately 3-fold less
induction of GFP compared to the effect of over 1,000-fold more ICP0
expressed from d105 (Fig. 6B). Thus, AdS.11E4(ICP0) can
efficiently transactivate gene expression despite the expression of
very low levels of ICP0.
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FIG. 6.
Expression level of ICP0 and transactivation of gene
expression. HEL cells were infected with HSV-1 IE mutant virus
d109 (MOI = 10) 24 h prior to superinfection with
10 PFU of d105 or 1,000 FFU of either AdS.11D or
AdS.11E4(ICP0) per cell. (A) Kinetics of ICP0 expression. Total
cellular protein was harvested at the indicated times
postsuperinfection and analyzed by Western blot for ICP0. Mock and
d109 lanes represent the 24 h.p.i. time point
indicated. d105 lanes represent 1/10 of the total protein
loaded in all other lanes. (B) Western blot of GFP induction. Samples
shown in panel A were analyzed for induction of GFP expression. The
labels above the lanes identified as AdS.11E4(ICP0) and d105
represent the fold-dilution of the sample in that lane relative to the
d109 sample lane. (C) Western blot of ICP0 expression. Total
protein samples obtained at the same 24 h.p.i. defined in panel A
and described in part B were analyzed by Western blot for ICP0. The
lanes identified as d105 are labeled as fold dilutions of
the input protein shown in the AdS.11E4(ICP0) lane. (D) Comparison of
the levels of ICP0 synthesized in wt HSV infection and during infection
with AdS.11E4(ICP0). HEL were cells infected with AdS.11E4(ICP0) (lane
1) or AdS.11D (lane 2) for 24 h as described above, or with
wild-type HSV-1, KOS at an MOI of 10 for the indicated times (hours)
postinfection (lanes 4 through 9). For these experiments, wild-type
HSV-1 (KOS) was adsorbed to cells at 4°C for 1 h, after which
time 37°C medium was added (t = 0 h.p.i.) and
incubation was continued at 37°C. At the indicated times (h.p.i.),
total cellular protein was harvested and analyzed by Western blot for
ICP0. Lanes 5 through 9 represent 1/10 the total protein loaded in all
other lanes. Lane 3 represents uninfected cells (M). The images on the
blot were directly quantified using a Molecular Dynamics Storm 840 set
to fluorescence-chemifluorescence. The method of quantification is
referred to in the text. (E) HEL cells infected with 1,000 PFU of
AdS.10, AdS11.D or AdS11.E4(ICP0) were monitored every 3 days for SEAP
expression.
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d105-infected cells overproduce ICP0 relative to wt
virus-infected cells. Thus, we were compelled to ascertain how the
levels of ICP0 in AdS.11E4(ICP0)- and wt HSV-infected cells compared and at what time postinfection with wt HSV these levels are similar. By
comparison, accumulation of ICP0 during the first 24 h of
infection with AdS.11E4(ICP0) was similar to that synthesized within
the first hour postinfection with wt HSV (Fig. 6D). Quantification of
the images of Fig. 6D revealed that the amount synthesized after 1 h of infection with KOS was 2.5 times that seen during infection with
AdS.11E4(ICP0). The maximum level of ICP0 synthesized in KOS infection
in the course of this experiment (6 h) was 48 times that synthesized
during AdS.11E4(ICP0) infection. Therefore, it is possible that
sufficient levels of ICP0 to activate gene expression during wt virus
infection accumulate within the first hour postinfection and that these
levels are considerably lower than the maximum level of accumulation
during infection.
In the absence of IE functions, the host cell very efficiently
represses HSV-1 genomes. As ICP0 can effectively relieve this repression and activate expression from such silenced promoters, it is
possible that ICP0 activity may also promote prolonged transgene expression by preventing the repression and shutoff of heterologous viral genomes in cis. Both AdS.11E4(ICP0) and
AdS.11D contain an HCMVIEp-SEAP transgene cassette in the E1 locus
(Fig. 1) which was used to assay transgene expression over time. While
AdS.11D retained SEAP expression levels above background, there was a noticeable decline in transgene expression within 10 days, which continued to decline through 36 days (Fig. 6E). In contrast, viruses that expressed either ICP0 from AdS.11E4(ICP0) or the E4 region from
AdS.10 retained significantly higher levels of SEAP expression for a
prolonged time. Thus, the presence of ICP0 can prolong gene expression
such that the kinetics of transgene expression were similar to those
seen in the presence of adenovirus E4 region.
Interaction with ND10 structures.
The experiment described
above suggests that both ICP0 and the adenoviral E4 region can function
to prolong transgene expression in cells. Both ICP0 (16, 36,
37) and E4orf3 protein (4, 26) have been
demonstrated to disrupt PML-containing nuclear domains (PODs or ND10),
resulting in the dispersal of ND10 components, such as PML, from their
usual residence in discrete, nuclear punctate structures of interphase
cells. The disruption of ND10 is postulated to be related to the gene
activation function of ICP0 as mutations in the ICP0 RING finger domain
fail to disrupt ND10 and are also impaired for gene activation function
(10, 16, 36). Thus, we were interested in the
interrelationship between ND10 disruption by adenovirus- or
HSV-1-expressed ICP0 compared to E4orf3 function with respect to
activation of gene expression. Expression of ICP0 from d105
resulted in loss of PML punctate staining as well as activation of the
HCMVIEp-GFP transgene encoded by the resident d109 genomes
(Fig. 7). Expression of ICP0 at low
levels from AdS.11E4(ICP0) similarly resulted in destruction of ND10
structures and activation of GFP expression. The control
E1 E4 adenovirus AdS.11D failed to alter
PML staining and did not activate expression from d109. In
the cases where the cells were mock infected or superinfected with
AdS.11D and AdS.10, both the high- and low-magnification fields showing
GFP-positive cells were selected because they contain a rare
GFP-positive d109-infected HEL cell. These presumably would be instances where the d109 genome or the appropriate part
of the d109 genome was in a state conducive to
transcriptional activity. Interestingly, under these conditions the
genomes are active without ND10 destruction in the cases of mock- and
AdS.11D-infected cells. As expected, infection with AdS.10, which
expresses E4orf3, resulted in PML disruption; however, GFP expression
from d109 was not activated. Thus, while PML destruction may
be involved in the mechanism of ICP0 activation, it is not a sufficient
condition to allow activation of viral gene expression. Additionally,
it may not be necessary, since the results of Fig. 7 demonstrate that
it is possible to have active human cytomegalovirus promoters on
d109 genomes in the absence of ND10 destruction.
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|
FIG. 7.
Disruption of ND10 and activation of gene expression.
The ability of ICP0 expressed from AdS.11E4(ICP0) to disrupt ND10 was
assayed by immunofluorescent staining of ND10 constituent PML as
described in Materials and Methods. Cells in the left column were
visualized prior to fixation by fluorescence microscopy for GFP
detection (20X objective). Cells in the middle column were visualized
after fixation by fluorescence microscopy for GFP detection (100X
objective plus oil). Micrographs in the right column represent the same
field as that in the middle row visualized for rhodamine isothiocyanate
detection (PML staining). Rows are identified as d109
infected plus respective superinfecting virus [top to bottom: mock,
AdS.11D, AdS.10, AdS.11E4(ICP0), d105].
|
|
Effect of adenovirus vectors on cellular proliferation.
The
disruption of ND10 was the only disturbance of cellular metabolism we
could observe following infection with AdS.11E4(ICP0). However, this
did not lead to obvious alterations in the phenotype of infected cells.
In fact, we did not observe any morphologic nor cytotoxic effects of
AdS.11E4(ICP0) infection on HEL cells, even at high MOIs (Fig. 1).
In contrast, d105-infected cells flatten, become enlarged,
fail to proliferate, and often display multiple subnuclei, with cell
death apparent within several days. We have previously shown that
ICP4 HSV-1 strains which express ICP0 exhibit a failure
of proliferation and decreased cell survival (23, 48, 58).
As a means to assess cell survival as a function of AdS.11E4(ICP0), we
monitored cellular proliferation following infection. As shown in Fig.
8, HEL cells infected with
d109 or AdS.11E4(ICP0) proliferated to the same extent as
mock-infected cells through 3 days postinfection, at which time cell
monolayers reached confluency. This is in contrast to the effect of
high-level expression of ICP0 from d105, which resulted in a
failure of proliferation and eventual cell death which was apparent by
48 hpi. The control E1 E3 E4
adenovirus, AdS.11D, also did not affect cellular proliferation. Thus,
despite disrupting ND10 structures, which have been associated with the proliferative status of the cell (31, 38),
AdS.11E4(ICP0) did not affect cellular proliferation.
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FIG. 8.
Effect of AdS.11E4(ICP0) on cellular proliferation. HEL
cells were infected with each indicated virus, and cell counts were
determined 1, 2, 3, and 4 days postinfection as indicated and described
in Materials and Methods.
|
|
Effect on cellular gene expression.
It is possible that the
mechanism of ICP0 activity in activating viral gene expression occurs
via manipulation of cellular factors potentially leading to
perturbation of cellular metabolic functions. This mechanism might then
also be expected to result in changes in the expression of cellular
genes as a direct or indirect consequence of ICP0 activity. We have
previously shown that the sole expression of ICP0 leads to changes in
the expression of a subset of cellular genes following infection
(23). We were interested in assessing the effect on
cellular gene expression patterns following infection with
AdS.11E4(ICP0) as a means of identifying potential toxic effects. In
particular, we were interested in comparing the effects of the viral
transactivators ICP0 and E4 in a similar background. To assess the
effects on cellular gene expression, we employed gene expression
microarrays to simultaneously assay the expression of >7,500 cellular
genes following infection with an E1 E3
adenovirus (AdS.10), an E1 E3
E4 adenovirus (AdS.11D), an E1
E3 E4 adenovirus expressing ICP0
[AdS.11E4(ICP0)], or an ICP0 expressing HSV-1 IE mutant virus
(d106). d106 is the virus that d105
was derived from (48). These viruses differ only in the
presence of the GFP expression cassette inserted in the deleted ICP27
locus of d106. d105 and d106 behave
identically with respect to the synthesis of ICP0 and their effects on
cells. We assayed expression at a time postinfection (48 h
postinfection [hpi]) when ICP0 expression and transactivation
function is apparent (Fig. 6) following infection with AdS.11E4(ICP0).
Figure 9 demonstrates that each of the
adenovirus mutants resulted in significantly fewer changes in the
expression of cellular genes than d106. The numbers of
differentially expressed cellular genes are 10, 18, 23, and 427, for AdS.10, AdS.11D, AdS.11E4(ICP0), and d106,
respectively. Differentially expressed genes are those whose expression
is increased or decreased by a factor of more than 2 as a consequence
of infection. The expression of E4 or ICP0 in the absence of E1 and E3
both resulted in a small number (8 and 13, respectively) of
differentially expressed genes compared to the E1
E3 E4 adenovirus, with most of the changes
representing induction events. Most of the remaining genes are those
that were differentially expressed with all three adenoviruses. Of note
is the observation that while d106 infection results in the
differential expression of 427 genes following infection, reduction of
ICP0 expression >1,000-fold following infection with
AdS.11E4(ICP0) reduced this number to 23, which is only 13 more than that seen in the absence of ICP0. This is consistent with the
lack of toxicity observed with this virus. Thus, the transactivation of
transgenes on viral genomes can be preserved without significantly
perturbing cellular gene expression by reducing the expression level of
ICP0 as by infection with AdS.11E4(ICP0).
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|
FIG. 9.
Effect on cellular gene expression patterns. The effect
of infection by AdS.11D (E1 E3
E4), AdS.11E4(ICP0) (E1 E3
E4 E4ICP0), and Ads.10 (E1
E3) adenovirus on cellular gene expression was assayed by
gene expression microarrays (A to C). Poly(A)+ mRNA from infected and
mock-infected cells was isolated at 48 h.p.i. For comparison,
microarray analysis of d106 at 6 hpi is also shown (D). The
mock-infected mRNA fraction was labeled with Cy5 while the infected
mRNA fraction was independently labeled with Cy3 and analyzed as
described in Materials and Methods. The scatter plots shown are in
log-log scales of fluorescent intensity read in each channel. Each gene
on the chip is represented by a single spot on the graphs. The diagonal
lines represent the fold increase or decrease in the infected cell
sample relative to the mock sample. The arrows in panels A to C
indicate the expression level of the adenovirus-encoded transgene
SEAP.
|
|
One of the cellular genes represented on the microarrays is alkaline
phosphatase, which cohybridizes to the SEAP transgene encoded by the
adenovirus mutant genomes shown in Fig. 1. The arrows in Fig. 9A to C
identify the expression profile of this gene. Note that the Cy3 signal
intensity for this gene is similar for each of the adenovirus vectors,
which indicates that transgene expression level is independent of
transactivator function at this time postinfection and is at a level
comparable to those of the mostly highly expressed genes in the cell.
This effect was also observed at the level of protein synthesis in Fig.
3. However, as shown in Fig. 6D, maintenance of adenovirus transgene expression requires transactivator function, which can efficiently be
supplied by either E4 or ICP0.
| |
DISCUSSION |
The role of HSV-1 ICP0 during infection is considered to be the
promotion of lytic cycle events via the ability of ICP0 to activate, or
derepress, viral gene expression facilitating the expression of the
regulated repertoire of lytic cycle viral genes. Activation of gene
expression by ICP0 occurs at the level of mRNA synthesis (27,
50), although ICP0 does not itself bind DNA. Thus, ICP0 activity
is likely mediated through complex interactions and manipulations of
host cell factors and metabolic pathways. Consequently, the effects of
ICP0 on the host may be functionally related to its mechanism of
action. Alternatively, such effects may be a reflection of downstream
effects of ICP0 action, which may also arise secondary to the
overexpression of ICP0 in some situations. In the present study, we
investigated the quantitative and functional consequence of ICP0
expressed at low abundance in a heterologous, adenovirus system absent
from the HSV-1 particle. We examined the consequences of such ICP0
expression and found it to retain wt function with respect to
activation and reactivation of viral gene expression, complementation
of virus replication, and reactivation of persistently infected
quiescent virus in an in vitro model. The amount of ICP0 synthesized
from the adenovirus was similar to that synthesized within the first
hour postinfection with wt HSV, suggesting that ICP0 could efficiently
function to activate gene expression very early in wt virus infection.
Furthermore, we demonstrate that such low-level expression of ICP0 does
not significantly perturb cellular metabolic function although ND10 structures were destroyed. The significance of these results has important implications for understanding ICP0's mechanism(s) of action
as well as for the utility of gene transfer studies.
We have extended previous studies in which ICP0 has been expressed in
adenovirus systems (6, 22, 37, 59, 60) with respect to
several important aspects. First, we have assessed the quantitative
requirement of ICP0 by expressing ICP0 from the endogenous adenovirus
E4 promoter in an E1 E4 adenovirus.
Previous studies have utilized E1 adenoviruses in which
either the adenovirus major late promoter or the native ICP0 promoter
drives ICP0 expression in the presence of endogenous E4 function. In
these contexts, ICP0 expression levels were shown to be similar to
those of HSV-1 (59, 60) as opposed to the very low
levels of ICP0 expressed from AdS.11E4(ICP0). Second, ICP0 encodes
activities that are potentially shared by adenovirus E4orf3, and thus
we have employed a defective adenovirus deleted for both E1 and E4
coding sequences to more accurately attribute effects to ICP0. In
particular, the disruption of ND10 is a shared function of ICP0 and
E4orf3; however, in our studies we differentiate the disruption of ND10
by these two viral proteins from activation of gene expression.
We previously demonstrated that expression of ICP0 results in
inhibition of cellular S phase and mitosis (23),
suggesting a role for cell cycle events in regulating HSV-1 gene
expression and/or replication. Indeed, it has been shown that ICP0
interacts with cyclin D3 (30), and that pharmacologic
inhibition of cyclin-dependent kinase reduces viral IE and E
transcription (28, 51, 52), indicating that cell cycle
dysregulation may relate to gene expression. While we did not directly
test whether these interactions occur in AdS.11E4(ICP0)-infected cells,
the low-level expression of ICP0 retained function with respect to gene
activation without affecting cellular proliferation. Thus, the cell
cycle arrest that occurs following expression of ICP0 from
ICP4 HSV-1 likely represents a dosage effect not
functionally related to its activation of gene expression function.
Additionally, while low levels of ICP0 expressed from
AdS.11E4(ICP0) remained capable of interacting with host cell
metabolic functions as demonstrated by disruption of ND10 structures
and alteration in the expression of a limited number of cellular genes
by expression array analysis, there was no obvious nor morphological
toxicity attributed as a result.
The apparent lack of toxicity in the presence of low levels of ICP0,
coupled with the retention of transgene expression is potentially
useful with respect to gene transfer efforts. The success of most viral
vector-based gene transfer strategies depends on absence of
vector-mediated toxicity as well as efficient transgene expression. In
HSV-1 systems, reducing toxicity involves deleting viral regulatory
functions to restrict viral gene expression patterns. Elimination of
HSV-1 toxicity requires deletion of all five IE functions
(48). Thus, viruses like AdS.11E4(ICP0) may have utility in gene transfer strategies due to the prolongation of gene expression and reduced toxicity. Given this observation, it may also be possible to engineer HSV-based vectors to express similarly low levels of ICP0.
However, the ability to reactivate quiescent HSV genomes despite the
low-level expression of ICP0 remains a continuing concern.
Additionally, we demonstrate that ICP0 expressed from an
E1 E3 E4 adenovirus can
enhance virus yield and plaquing efficiency of an HSV-1 mutant virus
with deletions of all five IE functions in complementing cell line FO6.
Thus, AdS.11E4(ICP0) provides a unique reagent to support the
production of higher-titer stocks of ICP0-deficient HSV-1 as well as
facilitate the quantification of resulting viral stocks. Another
observation that is relevant to gene transfer studies is the finding
that the expression of the transgene in all the adenoviruses tested
(SEAP) is at a level comparable to those of the most highly expressed
genes in the cell (Fig. 9). While the expression of transgenes from the
HCMV promoter in adenovirus is often used as a paradigm for efficient transgene expression, this high level is at the extreme of cellular gene expression, which may not be necessary or even desirable from the
standpoint of gene therapy.
From our results, it is clear that ICP0 can activate gene expression
without significantly affecting host cell function. We have previously
shown that ICP0 expression can result in the alteration in the
expression of a subset of cellular genes (23) under
conditions where ICP0 was greatly overexpressed relative to that from
AdS.11E4(ICP0). Presumably this overexpression contributed to the
observed toxicity. These differentially expressed cellular genes may
represent targeted cellular functions required for HSV-1 gene
expression and replication or may arise as consequence of nonspecific
ICP0 gene activation mechanisms. For example, ICP0 may facilitate
derepression of gene expression by altering the higher order structure
of chromatin. The effect of ICP0 on cellular metabolic function is
similar to the inhibition of histone deacetylase by trichostatin A such
as induction of p21, alteration in the expression of a subset of cellular genes, and derepression of cellular and viral gene expression (23). This suggests that ICP0 may alter the acetylation
state of core histones, resulting in derepression of gene expression. ICP0 expressed at low levels from AdS.11E4(ICP0) resulted in the differential expression of dramatically fewer cellular genes than when
it was expressed at high levels from HSV-1. Thus, if ICP0 possesses
activities that affect chromatin packaging, then HSV-1 genomes must be
more sensitive than cellular genomes or ICP0 activity must be targeted
to viral as opposed to cellular genomes. This possibility is currently
being addressed.
The targeting of viral genomes to ND10 and the disruption of
PML-containing nuclear structures by viral regulatory proteins has been
associated with several viral systems, including HSV (15, 25,
35) cytomegalovirus (1), adenovirus (4,
26), simian virus 40 (26), and Epstein-Barr virus
(55). One hypothesis is that ND10 represent the site of
deposition of input viral genomes where viral transcription is
initiated. Conversely, they could represent a cellular compartment
repressive for viral gene expression, as several ND10 protein
components are functionally linked to cellular interferon pathways
(5, 32, 53). This suggests that disruption of ND10 may be
a virus encoded mechanism to escape a cellular antiviral response and
would therefore be a necessary early event in the replication cycle of
many viruses by allowing efficient expression of viral genes. Studies
to assess the intranuclear location of persisting d109
genomes should help address this issue. However, our results indicate
that disruption of ND10 is not sufficient to turn on viral gene
expression, as an adenovirus which expresses E4 proteins disrupts ND10
but fails to activate expression from quiescent HSV-1 genomes. This
suggests that ICP0 possesses additional activities necessary for its
role in gene activation that E4 does not. It is unknown at present
whether ICP0 expressed at low levels in this system is capable of
mediating other previously identified interactions with cellular
proteins or functions such as DNA-dependent protein kinase (33,
40), translation factor EF1
(30), or ubiquitin/protein modification pathways (13, 14, 15, 17). Since ICP0 specifically and efficiently activated viral gene
expression, it is reasonable to propose that ICP0 possesses an
enzyme-like function such as that involving the proteasome-ubiquitin
pathway proposed by Everett and colleagues (13, 14) that
results in the destruction of ND10 and the modification of chromatin
structure at specific sites in the nucleus such as ND10. Studies to
address this hypothesis are currently under way.
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grants AI44812 and DK44935.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: E1257 Biomedical
Science Tower, Department of Molecular Genetics and Biochemistry, University of Pittsburgh School of Medicine, Pittsburgh, PA 15261. Phone: (412) 648-9947. Fax: (412) 624-0298. E-mail:
ndeluca{at}pitt.edu.
| |
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Abstract
Introduction
