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Journal of Virology, April 2001, p. 3636-3646, Vol. 75, No. 8
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.8.3636-3646.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Region of Herpes Simplex Virus Type 1 Latency-Associated Transcript Sufficient for Wild-Type Spontaneous
Reactivation Promotes Cell Survival in Tissue Culture
Melissa
Inman,1
Guey-Chuen
Perng,2
Gail
Henderson,1
Homayon
Ghiasi,2,3
Anthony B.
Nesburn,2,3
Steven L.
Wechsler,2,3 and
Clinton
Jones1,*
Department of Veterinary and Biomedical
Sciences, University of Nebraska, Lincoln, Nebraska
68583-09051; Ophthalmology Research
Laboratories, Cedars-Sinai Medical Center Burns & Allen Research
Institute, Los Angeles, California 900482; and
Department of Ophthalmology, UCLA School of Medicine, Los
Angeles, California 900243
Received 16 October 2000/Accepted 24 January 2001
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ABSTRACT |
The latency-associated transcript (LAT) is the only abundant herpes
simplex virus type 1 (HSV-1) transcript expressed during latency. In
the rabbit eye model, LAT null mutants do not reactivate efficiently
from latency. We recently demonstrated that the LAT null mutant
dLAT2903 induces increased levels of apoptosis in trigeminal ganglia of infected rabbits compared to LAT+
strains (G.-C. Perng, C. Jones, J. Ciacci-Zarella, M. Stone, G. Henderson, A. Yokht, S. M. Slanina, F. M. Hoffman, H. Ghiasi, A. B. Nesburn, and C. S. Wechsler, Science 287:1500-1503,
2000).The same study also demonstrated that a plasmid expressing LAT
nucleotides 301 to 2659 enhanced cell survival of transfected cells
after induction of apoptosis. Consequently, we hypothesized that LAT enhances spontaneous reactivation in part, because it promotes survival
of infected neurons. Here we report on the ability of plasmids
expressing different portions of the 5' end of LAT to promote cell
survival after induction of apoptosis. A plasmid expressing the first
1.5 kb of LAT (LAT nucleotides 1 to 1499) promoted cell survival in
neuro-2A (mouse neuronal) and CV-1 (monkey fibroblast) cells. A plasmid
expressing just the first 811 nucleotides of LAT promoted cell survival
less efficiently. Plasmids expressing the first 661 nucleotides or less
of LAT did not promote cell survival. We previously showed that a
mutant expressing just the first 1.5 kb of LAT has wild-type
spontaneous reactivation in rabbits, and a mutant expressing just the
first 811 nucleotides of LAT has a reactivation frequency higher than
that of dLAT2903 but lower than that of wild-type virus. In
addition, mutants reported here for the first time, expressing just the
first 661 or 76 nucleotides of LAT, had spontaneous reactivation
indistinguishable from that of the LAT null mutant
dLAT2903. In summary, these studies provide evidence that
there is a functional relationship between the ability of LAT to
promote cell survival and its ability to enhance spontaneous reactivation.
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INTRODUCTION |
Following ocular, oral, or
intranasal infection, herpes simplex virus type 1 (HSV-1) establishes
latent infection in trigeminal ganglia (TG) (3, 4). The
only abundant viral transcript expressed in latently infected neurons
is the latency-associated transcript (LAT) (11, 12, 32, 48, 51,
54). The primary 8.3-kb primary LAT transcript is unstable and
is spliced, yielding an abundant stable 2-kb LAT (12, 48, 53,
56) that is a stable intron (17, 33). LAT is
antisense to ICP0 and is primarily localized in the nucleus. This has
led to the suggestion that LAT represses ICP0 expression by an
antisense mechanism (48), which in turn represses
productive infection (8, 20). However, we previously
showed that the first 1.5 kb of the primary LAT is sufficient for
spontaneous reactivation from latency (45). Since this
region does not overlap ICP0, antisense repression of ICP0 expression
by LAT is not required for spontaneous reactivation in the rabbit
model. Although LAT is important for latency in small-animal models
(27, 52), its functional roles during the
latency-reactivation cycle are not understood.
In transient
transfection assays, a LAT fragment (LAT nucleotides 301 to 2659) encompassing the stable 2-kb LAT derived from strain KOS
enhanced cell survival following an apoptotic insult (42).
The same study also demonstrated that a McKrae LAT
mutant
(dLAT2903) had increased levels of apoptosis in rabbit TG.
These findings suggested that LAT is important for latent infections
because it promotes survival of infected neurons.
HSV-1 can induce or inhibit apoptosis (programmed cell death) in a cell
type-dependent manner after infection of cultured cells (1, 2,
18, 19, 36). Several antiapoptotic genes have been identified
(1, 2, 18, 42), suggesting that regulation of apoptosis is
crucial for the virus's life cycle. Trauma, stress, or other
imbalances of growth factors or cytokines can induce neuronal
apoptosis, and neuronal apoptosis is linked to neurodegenerative
disorders (7, 21, 23, 26, 35, 38-40). HSV-1 replication
and productive gene expression can occur in sensory ganglia during
acute infection and reactivation from latency (29-31,
50), which can lead to apoptosis in TG during acute infection
(42). Thus, the ability of HSV-1 to minimize neuronal
apoptosis may be an important aspect of the latency cycle.
In this study, we demonstrate that pLAT3.3, a plasmid expressing the
first 1.5 kb of the 8.3-kb primary HSV-1 McKrae LAT, promotes cellular
survival in CV-1 and neuro-2A cells following apoptosis induction. This
region does not overlap ICP0 and contains only 838 nucleotides of the
5' end of the stable 2-kb LAT intron. We also demonstrate that pLAT3.3
inhibited Bax-induced apoptosis in CV-1 cells. Additional plasmids
expressing smaller regions of LAT were constructed and tested. The
ability of these plasmids to promote cell survival correlated with the
ability of recombinant viruses expressing the corresponding LAT
fragments to spontaneously reactivate in the ocular rabbit model of
HSV-1 latency. This suggests that the ability of LAT to promote cell
survival after induction of apoptosis plays an important role at one or
more steps in the HSV-1 latency cycle.
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MATERIALS AND METHODS |
Cells and viruses.
Cells were plated at a density of 5 × 105 cells/100-mm plastic dish in Earl's modified
Eagle's medium supplemented with 5% fetal bovine serum. All medium
contained penicillin (10 U/ml) and streptomycin (100 µg/ml). CV-1
cells were split at a 1:5 ratio every 4 or 5 days. Neuro-2A cells were
obtained from the American Type Culture Collection (Rockville, Md.) and
split in a 1:4 ratio every 3 to 5 days.
All parental and mutant viruses were plaque purified three times and
passaged only one or two times prior to use. Wild-type McKrae,
dLAT2903, dLAT2903R, LAT3.3A (originally
designated LAT1.5a), and LAT2.6A have been described previously
(16, 44, 45). Rabbit skin (RS) cells, used for preparation
of virus stocks and for culturing rabbit tear films, were grown in
Eagle's minimal essential medium supplemented with 5% fetal calf
serum (FCS).
Bluo-gal cotransfection and analysis of cell death.
Cells
were plated at a density of 2 × 105/well in six-well
plastic plates (35 mm2/well) 12 to 16 h prior to the
transfection. Cells were transfected with a human cytomegalovirus (CMV)
expression vector containing the 
-galactosidase gene (pCMV--Gal)
and one of the plasmids described below by the calcium phosphate
method. For each 35-mm well, 250 µl of a calcium phosphate solution
(125 mM CaCl2, 25 mM HEPES-NaOH [pH 7.1], 0.75 mM
Na2HPO4-NaH2PO4 [pH
7.0], 125 mM NaCl) and the designated amount of plasmid DNA mixture
were added to the cells. Five hours after transfection, cells were shocked with 20% glycerol-phosphate-buffered saline (PBS) solution for 4 min and then washed with PBS twice. Fresh medium containing 5%
FCS and 5 mM sodium butyrate was added to the cells to enhance expression of genes encoded by plasmids, because sodium butyrate can
inhibit histone deacetylase activity (5). Long-term
treatment of cell lines with sodium butyrate can lead to apoptosis
(22, 49). When CV-1 cells are treated with 5 mM sodium
butyrate for 16 h, we have seen an approximately twofold increase
in apoptosis, as judged by measuring ONA content (data not shown). When
CV-1 cells are treated for 40 to 48 h with sodium butyrate, we can routinely detect 7 to 12 times more apoptosis than in control cultures.
The cells from each well were incubated at 37°C for 16 h and
then subcultured at a 1:5 ratio onto a 24-well dish. These cells were
treated with 15 µM etoposide or 5 mM sodium butyrate (37°C for 48 h), and -galactosidase expression was analyzed as described
previously (9, 10, 25, 42). Briefly, cells were rinsed
with calcium- and magnesium-free PBS (CMF-PBS), fixed with 2%
formaldehyde-0.2% glutaraldehyde in PBS for 5 min, and then washed
twice with CMF-PBS. Fixed cells were stained for 6 to 24 h with
0.1% Bluo-gal (Gibco) in a PBS solution which contained 5 mM potassium
ferrocyanide, 5 mM potassium ferricyanide, and 2 mM MgCl2.
After rinsing in PBS, positive cells were observed microscopically, and
the average number of blue-stained cells was counted. At least five
fields per plate were counted, and the average number of cells per
field was calculated.
The Bax expression plasmid used in this study was purchased from
Upstate Biotechnology (Lake Placid, N.Y.). The Bcl-2 expression
plasmid
was obtained from John Reed (San Diego, Calif.).
Construction of LAT2.5A and LAT1.8A.
LAT1.8A contains the
LAT promoter plus the first 76 nucleotides of the primary LAT RNA in
the unique long region between UL37 and UL38. LAT2.5A contains the LAT
promoter and the first 661 nucleotides of the primary LAT RNA in the
same novel location. The parental virus for both constructs was
dLAT2903, a mutant of HSV-1 strain McKrae containing a
1.8-kb (EcoRV-HpaI) deletion in both copies of
LAT that removed 0.2 kb of the LAT promoter and 1.6 kb of the 5' end of
the primary 8.3-kb LAT transcript (44).
dLAT2903 transcribes no LAT RNA and reactivates poorly relative to LAT+ viruses (wild type or
dLAT2903R). These mutants were constructed as previously
described for LAT3.3A (originally designated LAT1.5a) and LAT2.6A
(16, 43, 44, 46) except for the size of the structural
portion of the LAT gene included with the LAT promoter (shown
schematically in Fig. 5). Briefly, an HSV-1 McKrae restriction fragment
containing LAT nucleotides 
1793 to +76 (the LAT promoter plus the
first 76 nucleotides of the primary LAT) or LAT nucleotides 1793 to
+661 (the LAT promoter plus the first 661 nucleotides of the primary
LAT) was inserted into a uniquely constructed PacI site
between the HSV-1 McKrae genes UL37 and UL38 contained in plasmid
pV375Pac (45). LAT1.8A and LAT2.5A were each generated by
cotransfection and homologous recombination of infectious
dLAT2903 viral DNA with the LAT1.8A or LAT2.5A plasmid as we
previously described (45). Following cotransfection,
isolated plaques were picked and screened for the proper insertion
between UL37 and UL38 by restriction digestion and Southern analysis.
Selected plaques were plaque purified three times and grown into virus stocks. Virus stocks were analyzed by restriction enzyme digestion and
Southern blots to confirm that the correct LAT fragment was present
between UL37 and UL38. This analysis also verified that both long
repeats retained the original deletion (the 1.8-kb LAT promoter and the
first 1.6 kb of the 5' end of the primary LAT transcript) in both viral
long repeats.
Rabbits.
New Zealand White male rabbits (Irish Farms), 8 to
10 weeks old, were used for all experiments. Rabbits were treated in
accordance with the Association for Research in Vision and
Ophthalmology, American Association for Laboratory Animal Care, and
National Institutes of Health guidelines.
Rabbit model of ocular HSV-1 infection, latency, and spontaneous
reactivation.
Rabbits were bilaterally infected without
scarification or anesthesia by placing 2 × 105 PFU of
HSV-1 per eye into the conjunctival cul-de-sac, closing the eye, and
rubbing the lid gently against the eye for 30 s (16, 42, 44, 45,
47). At this dose of HSV-1 McKrae, virtually all of the
surviving rabbits harbor a bilateral latent HSV infection in both TG,
resulting in a high group rate of spontaneous reactivation. Latency is
assumed to be established by 28 days postinfection. Acute ocular
infection of all eyes was confirmed by HSV-1-positive tear film
cultures collected on day 3 or 4 postinfection.
Detection of spontaneous reactivation by ocular shedding.
Beginning on day 30 postinfection, tear film specimens were collected
daily from each eye for 26 days as previously described (16, 42,
44, 45, 47), using a nylon-tipped swab. The swab was then placed
in 0.5 ml of tissue culture medium and squeezed, and the inoculated
medium was used to infect RS cell monolayers. These monolayers were
observed in a masked fashion by phase light microscopy for up to 7 days
for HSV-1 cytopathic effects (CPE). All positive monolayers were blind
passaged onto fresh cells to confirm the presence of virus. Viral DNA
was purified from randomly selected positive cultures derived from
latently infected rabbits and analyzed by restriction enzyme digestion
and Southern blots to confirm that the CPE was due to reactivated HSV-1
and that the reactivated virus was identical to the input virus.
Statistical analyses were performed using Instat, a personal computer
software program. Results were considered statistically
significant
when the
P value was <0.05.
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RESULTS |
Localization of McKrae LAT sequences that promote cell
survival.
Our previous study demonstrated that in
transient-transfection assays, a plasmid expressing LAT nucleotides 301 to 2659 from HSV-1 KOS promoted cell survival after induction of
apoptosis and that the HSV-1 McKrae LAT reduces apoptosis frequency in
TG of infected rabbits (42). To confirm that McKrae LAT
would also promote cell survival after apoptosis induction in cultured
cells and to further map the involved LAT region, LAT plasmids were constructed from McKrae (Fig. 1). These
plasmids contain the LAT promoter but do not possess a strong exogenous
poly (A) addition site at their 3' terminus, suggesting that
transcripts synthesized from these constructs would not have
polyadenylated tails. The ability of LAT fragments to inhibit apoptosis
was measured by cotransfecting cells with a -Gal expression plasmid
(pCMV--Gal) and the designated LAT constructs (9, 10, 25, 34,
42). Apoptosis was then induced by treating the cultures with 5 mM sodium butyrate or 15 µM etoposide. Both chemicals induce
apoptosis in a variety of cells (5, 6, 22, 37, 49). Monkey
kidney (CV-1) or mouse neuroblastoma (neuro-2A) cells that are
transfected with pCMV--Gal have fewer blue cells when apoptosis
is induced (9, 10, 47). If the LAT plasmid inhibits
apoptosis, the number of -Gal+ cells will be higher than
in the empty vector control.
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FIG. 1.
Schematic representation of plasmid inserts tested for
antiapoptosis activity in transient-transfection assays. LAT, shown at
the top, indicates the relative location of the LAT promoter, the
primary 8.3-kb LAT RNA, and the stable 2-kb LAT intron (black box). The
region downstream of the 2-kb LAT contains a break and is not drawn to
scale. APALAT contains the Moloney murine leukemia virus (MoMLV) long
terminal repeat (LTR) driving expression of LAT (nucleotides 301 to
2659) from HSV-1 strain KOS. The remaining LAT fragments are all
derived from HSV-1 strain McKrae. The portion of the LAT promoter in
pEV (161 to +76) is sufficient for high transcription levels in
transient-transfection assays. pEV(pro) is identical to pEV but
without the promoter. The LAT fragments in pLAT3.3, pLAT2.6, pLAT2.5,
and pLAT1.8 correspond to the UL37-UL38 LAT inserts in the LAT3.3A,
LAT2.6A, LAT2.5A, and LAT1.8A mutant viruses shown in Fig. 5,
respectively.
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We have previously characterized the effects that several chemicals
have on apoptosis using CV-1 cells (
9,
10,
42)
and have
shown that the APALAT fragment (Fig.
1) protects CV-1
and neuro-2A
cells from apoptosis (
42). Since the latency model
used
for McKrae is the rabbit, rabbit skin cells could have been
used to
examine apoptosis. However, we thought that for the purposes
of mapping
the region within LAT that protects against apoptosis,
it was logical
to employ the cells we used previously. In addition,
CV-1 cells
efficiently support HSV-1 productive infection and
LAT transcription.
Neuro-2A cells retain many neuronal characteristics,
and there are no
available neuron-like cell lines derived from
rabbits.
Following treatment with etoposide or sodium butyrate, APALAT (KOS
nucleotides 301 to 2659) and the antiapoptotic baculovirus
gene
cpIAP both had a higher frequency of cell survival than a
blank
expression vector (pcDNA3.1) (Fig.
2).
Neuro-2A cells transfected
with pLAT3.3 also had increased cell
survival relative to cells
transfected with pcDNA3.1 following
treatment with sodium butyrate
or etoposide. pLAT3.3 also enhanced cell
survival in CV-1 cells
treated with sodium butyrate. In both cases, the
increased survival
with pLAT3.3 was similar to that seen with APALAT.
This confirms
that McKrae LAT and KOS LAT can both enhance cell
survival after
apoptosis induction with similar efficiency.
Furthermore, it suggests
that the cell survival domain resides in the
region common to
both plasmids, which is bounded by LAT nucleotides 301 to 1499.
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FIG. 2.
Efficiency of cell survival after transfection with LAT
constructs. Deletion plasmids of LAT are shown in Fig. 1. CV-1 and
neuro-2A (2A) cells were transfected with LAT constructs (4 µg of
DNA) and pCMV--Gal (1 µg of DNA). Cells were treated with sodium
butyrate (Na-But, 5 mM) or etoposide (Etop, 15 µM) to induce
apoptosis. Cell survival was measured by counting -Gal+
cells at 48 h after transfection as described previously (9,
10, 42). The number of -Gal+ cells that were
present in cultures transfected with pCMV--Gal plus pcDNA3.1
without etoposide or sodium butyrate treatment was set at 100%. The
values are the means of five different experiments.
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Etoposide did not consistently induce apoptosis in CV-1 cells and thus
was not used for this study. Cultures of CV-1 and neuro-2A
cells
transfected with pLAT2.5, pLAT2.4, or pLAT1.8, had levels
of cell
survival similar to those in cultures transfected with
pcDNA3.1 after
apoptosis induction. This suggested that expression
of LAT nucleotides
1 to 661 (pLAT2.5) or less (pLAT2.4 and pLAT1.8)
was unable to protect
cells from apoptosis. As expected, the promoterless
LAT fragment
pLAT1.0 also was not able to promote cell
survival.
Interestingly, pLAT2.6, expressing LAT nucleotides 1 to 811, had cell
survival values that were lower than those for pLAT3.3
and APALAT but
slightly higher than those for the other deletion
constructs or the
empty plasmid. This suggested that LAT nucleotides
1 to 811 retained a
small amount of activity but that additional
sequences were required
for efficient cell survival, as seen with
the larger LAT plasmids
(i.e., LAT nucleotides 1 to 1499 or 301
to 2659). CV-1 and neuro-2A
cells transfected with pEV, a construct
containing the first 1.5 kb of
LAT and the minimal LAT promoter,
also exhibited enhanced cell survival
relative to those transfected
with pcDNA3.1. The enhanced cell survival
was similar to that
of both pLAT3.3 and APALAT, consistent with this
promoter having
high activity in these cells (
56). When
the promoter was deleted
[pEV(pro
)], cell survival was not
enhanced, demonstrating that
expression of LAT was necessary for its
cell survival
activity.
Although the data in Fig.
2 suggested that LAT products inhibited
apoptosis in transiently transfected cells, one could argue
that LAT
transactivated the CMV immediate-early promoter in the
CMV-
-Gal
plasmid and that this resulted in increased numbers
of
-Gal
+ cells. To eliminate this possibility, the pEV
construct was cotransfected
with a CMV-chloramphenicol
acetyltransferase (CAT) construct,
and CAT activity levels were
measured. In three independent experiments,
pEV did not activate the
CMV promoter (Fig.
3A). The intensity
of
the blue cells and the number of blue cells were similar when
LAT (pEV)
or a blank expression vector (pNEB193) (Fig.
3B) was
cotransfected with
pCMV-
-Gal, which was consistent with the inability
of pEV to
transactivate the CMV promoter. After etoposide treatment,
the number
of
-Gal
+ cells decreased less when CV-1 cells were
cotransfected with
pEV in addition to pCMV-
-Gal. Since etoposide
induces apoptosis
in a variety of mammalian cells (
5,
22,
49), a reduction
in
-Gal
+ cells after etoposide
treatment is indicative of apoptosis, as
we concluded previously
(
9,
10,
42).
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FIG. 3.
LAT does not activate the CMV promoter. (A) CV-1 and
neuro-2A cells were transfected with pCMV cat (2 µg) and the
indicated amounts of plasmid pEV (Fig. 1). Blank expression vector
(pNEB193) was used to maintain the same amounts of plasmid for each
transfection. At 48 h after transfection, CAT enzymatic activity
was measured as described previously (13, 14, 28). The
percent acetylated chloramphenicol (%Ac-CM) was quantified using a
PhosphoImager. (B) CV-1 cells were cotransfected with pCMV--Gal (1 µg of DNA) and pNEB193 (4 µg of DNA) or pEV (4 µg of DNA). Some
cultures were treated with etoposide (15 µM) at 16 h after
transfection to induce apoptosis. At 48 h after transfection,
cells were stained to detect -Gal+ cells. Representative
panels are shown.
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LAT sequences inhibit Bax-induced apoptosis.
Bax is an
important proapoptotic protein that interacts with the mitochondrial
membrane, promotes cytochrome c release, and thus activates
Apaf-1 (apoptosis-activating factor-1) (41, 55). Activated
Apaf-1 initiates a caspase cascade that precedes the cytological and
biochemical events leading to apoptosis. The Bcl-2 protein interacts
with Bax and thus inhibits apoptosis. A CMV expression vector
containing Bax reduced the number of -Gal+ CV-1 cells
(Fig. 4A) and neuro-2A cells (data not
shown). To determine if LAT could inhibit Bax-induced apoptosis, cells
were cotransfected with Bax, pEV, pEV(pro) and pCMV--Gal. A
dose-dependent increase in -Gal+ cells was observed when
increasing amounts of the pEV construct were cotransfected with Bax. In
contrast, the pEV (pro) construct had no effect on Bax-induced
apoptosis, indicating that expression of LAT was necessary for
promoting cell survival. As expected, Bcl-2 interfered with Bax-induced
apoptosis and was more efficient than the pEV construct.
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FIG. 4.
LAT interferes with Bax-induced apoptosis. (A) CV-1
cells were cotransfected with the designated LAT construct or a CMV
expression vector containing Bcl-2 (2, 4, or 8 µg of DNA), Bax (2 µg of DNA), and pCMV--Gal (1 µg of DNA). To maintain constant
amounts of DNA, a blank expression vector (pcDNA3.1) was added to the
mixture. At 48 h after transfection, the number of
-Gal+ cells was counted. The number of
-Gal+ cells present in control cultures (1 µg of
pCMV--Gal and 9 µg of pcDNA3.1) was set at 100%. The values are
the means of four different experiments. (B to E) After -Gal
staining, cellular DNA was stained with Hoescht 3342 as described
previously (13). -Gal+ cells were
identified using phase contrast microscopy, and DNA staining of the
same cell was visualized by fluorescence. Arrows denote
-Gal+ cells. (B) CV-1 cells transfected with Bax (2 µg
of DNA). (C) CV-1 cells transfected with a blank expression vector,
pcDNA3.1. (D) CV-1 cells transfected with Bax (2 µg of DNA) and
APALAT (8 µg of DNA). (E) CV-1 cells transfected with Bax (2 µg of
DNA) and pEV (8 µg of DNA). For panels B to E, pCMV--Gal (1 µg
of DNA) was included in each transfection. A blank expression vector
(pcDNA3.1) was added to the mixture to maintain the same amount of DNA
(8 µg of DNA for each sample). An asterisk denotes an apoptotic cell,
as judged by the presence of condensed chromatin and apoptotic
bodies.
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The
-Gal
+ cells (blue cells) transfected with Bax were
compared to those cotransfected with Bax and APALAT or Bax and pEV
by
specifically staining DNA with Hoescht 33342. This procedure
allows one
to identify
-Gal
+ cells using phase contrast microscopy
and then visualize chromatin
by fluorescence.
-Gal
+
cells transfected with Bax had condensed chromatin and more frequently
contained apoptotic bodies (Fig.
4B) compared to cells transfected
with
the empty vector (Fig.
4C). In contrast,
-Gal
+ cells
from cultures cotransfected with Bax plus APALAT (Fig.
4D) or Bax plus
pEV (Fig.
4E) had less condensed chromatin and
had nuclear morphology
similar to that of normal cells. Of 200
-Gal
+ cells that
were transfected with Bax alone, 86% had condensed
chromatin and thus
were apoptotic. Only 20% of the
-Gal
+ cells transfected
with Bax and pEV or Bax and APALAT appeared
to be apoptotic. Thus, LAT
(both pEV and APALAT) interfered with
Bax-induced
apoptosis.
Lack of spontaneous reactivation by LAT1.8A and LAT2.5A.
To
determine if the ability of LAT to interfere with apoptosis correlated
with spontaneous reactivation, additional LAT deletion mutants were
constructed and tested in the rabbit ocular latency model. The genomic
structures of wild-type HSV-1 McKrae, dLAT2903, dLAT2903R, LAT3.3A, LAT2.6A, LAT2.5A, and LAT1.8A are shown
in Fig. 5. All viruses
were derived from HSV-1 strain McKrae. The construction and properties
of dLAT2903, its marker-rescued virus dLAT2903R,
LAT3.3A, and LAT2.6A have been described previously (16, 44,
45). Wild-type McKrae contains two copies of LAT, one in each
viral long repeat. dLAT2903 contains a deletion in both
copies of LAT from 161 to +1677 relative to the start of the primary
LAT transcript (Fig. 5B, indicated by XXXXX). This virus is missing key
promoter elements, makes no LAT RNA, and is a true LAT null mutant.
Insertion of 1.8 kb of the LAT promoter and different lengths of LAT
into a unique PacI site that was constructed between UL37
and UL38 (Fig. 5C, D, E, and F) gave LAT3.3A, LAT2.6A, LAT2.5A, and
LAT1.8A from dLAT2903. Due to the complete deletion of the
LAT promoter and the first 1.67 kb of the primary LAT transcript, none
of these mutants are capable of transcribing any LAT RNA from either
copy of LAT in the long repeats (16). As previously shown
for LAT3.3A and LAT2.6A (46, 47), these mutants do,
however, transcribe the expected region of LAT from their ectopic
insert. LAT3.3A, LAT2.6A, LAT2.5A, and LAT1.8A make the first 1,499, 811, 661, and 76 nucleotides of the primary LAT, respectively.
Additional details of the construction of these viruses are given in
Materials and Methods.
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FIG. 5.
Structures of LAT mutant viruses. (A) Schematic
representation of wild-type HSV-1 and marker-rescued
dLAT2903R. The prototypic orientation of HSV-1 shown here
contains a unique long (UL) region and a unique short
(US) region (solid lines), each bounded by inverted repeats
(open rectangles). TRL, long terminal repeat;
IRL, long internal repeat; TRS, short terminal
repeat; IRS, short internal repeat. The dashed lines under
the genome indicate a blow up of the repeat regions. Arrows indicate
the locations and directions of the LAT, ICP34.5, and ICP0 transcripts.
The solid rectangle within the primary 8.3-kb LAT transcript indicates
the location of the stable 2-kb LAT intron. TATA indicates the location (in the genomic DNA) of the LAT promoter TATA box. (B)
Previously described LAT deletion mutant dLAT2903
(44), which contains a 1.8-kb deletion (161 to +1667) in
both copies of the LAT gene (one in each long repeat), indicated by
XXXX, makes no LAT RNA, and reactivates poorly. (C) Mutant LAT3.3A,
which was previously designated LAT1.5a (45). A blow up
shows the 1.8-kb LAT promoter and the first 1.5 kb of the LAT
transcript inserted between genes UL37 and UL38 in the unique long
region of the LAT deletion mutant dLAT2903. LAT3.3A
transcribes only the first 1.5 kb of LAT yet has wild-type spontaneous
reactivation. (D, E, and F) LAT2.6A (16), LAT2.5A, and
LAT1.8A, respectively, containing the LAT promoter and the first 811 nucleotides of the LAT transcript, the LAT promoter and the first 661 nucleotides of LAT, and the LAT promoter alone (up to LAT nucleotide
+76), respectively, inserted between UL37 and UL38 of
dLAT2903. LAT2.6A has a spontaneous reactivation midway
between that of the wild type and dLAT2903
(16). LAT2.5A and LAT1.8A are described here for the first
time and have spontaneous reactivation rates similar to that of
dLAT2903.
|
|
As with the LAT null mutant
dLAT2903 (
44),
LAT1.8A and LAT2.5A were wild type for replication in tissue culture,
replication
in rabbit eyes, induction of eye disease in rabbits, and
neurovirulence,
as judged from rabbit survival (data not shown). To
examine spontaneous
reactivation, 18 rabbits/group were infected with
2 × 10
5 PFU of LAT1.8A,
dLAT2903,
dLAT2903R, or LAT3.3A per eye. In a
separate experiment, 28 or 29 rabbits/group were similarly infected
with LAT2.5A,
dLAT2903, or LAT3.3A. Beginning 30 days postinfection
(at
which time latency had already been established), the eyes
from all
surviving rabbits were swabbed once a day for 26 days
to collect tear
films for analysis of reactivated virus as described
in Materials and
Methods. The cumulative number of virus-positive
tear film cultures is
shown in Fig.
6A and B. Because there
were
minor, nonsignificant differences in the numbers of surviving
rabbits in the different groups within each experiment, the data
were
standardized to represent cumulative positive cultures per
eye. The
cumulative spontaneous reactivation rate in rabbits latently
infected
with LAT1.8A (Fig.
6A, approximately one positive culture
per eye on
day 26) appeared to be less than that in rabbits infected
with
dLAT2903R or LAT3.3A (Fig.
6A, approximately 3 to 3.5 per
eye on day 26) and similar to that in rabbits infected with
dLAT2903
(Fig.
6A, approximately 1 per eye). Similarly,
cumulative spontaneous
reactivation of LAT2.5A appeared to be less than
that of LAT3.3A,
which has wild-type spontaneous reactivation
(
45), and similar
to that of
dLAT2903 (Fig.
6B).
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 6.
Cumulative spontaneous reactivation of LAT2.5A and
LAT1.8A. Rabbits were ocularly infected with dLAT2903,
dLAT2903R, LAT3.3A, LAT1.8A, or LAT2.5A. Beginning on day 30 postinfection (p.i.) (day 1 of tear film collection), at which time
latency had been established, tear films were collected daily for 26 days. These samples were then plated on RS cell monolayers and observed
for the presence of CPE, which is indicative of spontaneously
reactivated virus in the tears. Positive cultures were passaged, and
DNA was analyzed. Southern analysis confirmed that the CPE was due to
HSV-1 and that the mutant spontaneously reactivated viruses retained
their deletions. The y axis represents the cumulative number
of HSV-1-positive cultures for each virus group divided by the number
of eyes in the group. Panels A and B show results from separate
experiments. Statistical analyses are shown in Table 1.
|
|
In the first experiment, the number of positive eye cultures (Table
1) indicated that only 3% of the tear
film cultures from
rabbits latently infected with LAT1.8A contained
spontaneously
reactivated virus. This was similar to the number with
dLAT2903
(3.6%) but significantly less than that with
dLAT2903R (13.7%)
and LAT3.3A (12.2%) (Table
1). In the
second experiment, only
0.6% of the tear film cultures from rabbits
latently infected
with LAT2.5A contained spontaneously reactivated
virus (Table
1). This was similar to the number with
dLAT2903 (0.4%) and significantly
less than that with
LAT3.3A (6%) in this experiment (Table
1).
Because the above analyses
do not take into account the number
of eyes in each of the groups, the
data were also analyzed as
follows. The percentage of days on which
virus-positive cultures
were obtained for each eye in each group (i.e.,
the percentage
of time that each eye was positive for spontaneous
reactivation)
was calculated, plotted as scattergrams, and analyzed by
analysis
of variance (ANOVA) (Fig.
7).
This is a very powerful and stringent
analysis because it takes into
account both the number of eyes
in each group and the duration of the
study in one calculation.
By this analysis, LAT1.8A reactivated
similarly to
dLAT2903 but
less efficiently than
dLAT2903R and LAT3.3A (Fig.
7A). This analysis
also
confirmed that LAT2.5A reactivated similarly to
dLAT2903
but
less efficiently than LAT3.3A (Fig.
7B). Thus, mutant viruses
capable
of expressing just the first 76 or 661 nucleotides of
LAT from the LAT
promoter had impaired spontaneous reactivation
similar to the LAT null
mutant. This correlates with the inability
of these same LAT regions to
promote cell survival after apoptosis
in tissue culture, as described
above.
View larger version (14K):
[in this window]
[in a new window]
|
FIG. 7.
Scattergram representation of spontaneous reactivation.
Each data point represents the percentage of days during the 26-day
observation period on which individual eyes were positive for
spontaneously reactivated virus. To visually separate the individual
data points, some of the zero points are plotted slightly below zero.
The P values (ANOVA, Tukey post test) in panel A are
relative to LAT1.8A. The P values in panel B are relative to
LAT2.5A. dLAT, dLAT2903; dLATR, dLAT2903R.
|
|
In the experiments shown in Fig.
7 and Table
1, the spontaneous
reactivation rates of the wild-type viruses LAT3.3A and
dLAT2903R
(Fig.
7A) are higher than that of the wild-type
virus LAT3.3A
(Fig.
7B). This type of variation between experiments is
common
and is believed to be due to undetermined environmental factors
(unpublished observations). However, within a single experiment,
the
relative spontaneous reactivation rates between wild-type
and
LAT
viruses always remained similar. This illustrates the
importance
of including wild-type and LAT
control viruses
in each experiment and of housing all rabbits
in each experiment in the
same
room.
| |
DISCUSSION |
The first 1.5 kb of the primary LAT (LAT3.3A) is sufficient to
restore wild-type levels of spontaneous reactivation to a LAT null
mutant (45). We show in this study that expression of the same fragment in a plasmid (pLAT3.3) promotes cell survival after apoptosis induction. The first 811 nucleotides of the primary LAT
(LAT2.6A) only partially restore spontaneous reactivation to a LAT null
mutant (16). We showed here that this LAT region (pLAT2.6)
similarly only partially promoted cell survival after apoptosis
induction. Further deletion of the LAT region (LAT2.5A and LAT1.8A) did
not allow spontaneous reactivation or cell survival (pLAT2.5 and
pLAT1.8). Thus, the results presented here show a correlation between
the region of LAT capable of enhancing spontaneous reactivation in
rabbits and the region of LAT capable of promoting cell survival after
induction of apoptosis by chemicals or Bax. It should be pointed out
that LAT's ability to inhibit apoptosis could enhance spontaneous
reactivation by at least two distinct mechanisms. First, LAT could
enhance spontaneous reactivation at the level of establishment or
maintenance by enhancing neuronal survival during acute infection. The
finding that a LAT null mutant (dLAT2903) has higher levels
of apoptosis in TG during acute infection than LAT+ strains
(42) supports a role for LAT in maximizing the number of
neurons that survive acute infection. Second, it is also possible that
LAT directly stimulates reactivation by prolonging survival of neurons
as well as nonneuronal cells during spontaneous reactivation, thus
maximizing virus production. Although the studies presented here
correlate enhancement of cell survival with the ability of LAT to
promote spontaneous reactivation in latently infected rabbits, they do
not exclude the possibility that LAT has additional functions that are
necessary for lifelong latency in humans.
Neuro-2A and CV-1 cells were used for these studies because we
previously found that LAT had a positive effect on cell survival in
these cell lines. Since there is a correlation between LAT's inhibiting apoptosis in these cell lines and promoting spontaneous reactivation in rabbits, there appears to be biological relevance to
the findings that we observed in CV-1 and neuro-2A cells. In contrast,
LAT had no effect on cell survival in two transformed cell lines, 293 (human epithelial cells immortalized by adenovirus) and COS-7 (CV-1
cells transformed by simian virus 40) (data not shown). These viruses
encode oncogenes that interfere with the growth-suppressing properties
of p53 and retinoblastoma protein and impair the proapoptotic functions
of p53. In general, expression of these viral oncogenes confers
resistance to apoptosis. We found that when a chemical agent was able
to overcome these dominant antiapoptotic viral oncogenes and induce
apoptosis in 293 and COS-7 cells, LAT was not able to promote survival.
Interestingly, in CV-1 and neuro-2A cells, the same chemicals had
different effects on cell death. For example, etoposide did not
effectively kill CV-1 cells but did induce apoptosis in neuro-2A cells.
Furthermore, ceramide effectively induced apoptosis in CV-1 cells
(9, 10, 42) but not in neuro-2A cells (data not shown).
Several different apoptotic pathways are regulated by numerous factors.
During immortalization or transformation of mammalian cells, the
apoptotic pathways may be altered, resulting in the generation of
long-lived cell lines that grow continuously. Thus, it is difficult to
make sweeping conclusions about the ability of LAT to interfere with
cell death induced by Bax or the chemicals used in this study. In spite
of these shortcomings, one can conclude that LAT has the potential to
inhibit cell death, which is consistent with previous findings
(42). In particular, LAT can interfere with Bax-induced
apoptosis in CV-1 cells.
Because the stable 2-kb LAT is easily detected during neuronal latency
while the remaining LAT RNA is difficult to detect, the term LAT is
sometimes used to refer to the 2-kb LAT rather than the primary 8.3-kb
transcript. We showed here that a plasmid expressing the first 1.5 kb
of the primary 8.3-kb LAT promotes cell survival as efficiently as a
plasmid expressing the entire 2-kb LAT. This 1.5-kb region contains
only the first 838 nucleotides of the 2-kb LAT, and none of this RNA
has the stability of the intact 2-kb LAT (45). Thus, as we
showed previously for spontaneous reactivation (45),
neither the entire 2-kb LAT nor stability of the LAT RNA is required
for promoting cell survival after apoptosis induction.
Although the 1.5-kb transcript contains several small open reading
frames (ORFs), they are not well conserved among HSV strains KOS,
McKrae, and 17syn+, even though LATs from all three of these strains
can promote efficient spontaneous reactivation (15). This
suggests that these ORFs are not expressed or not important or that
their functional domains are small and not very obvious. The lack of an
obvious poly(A) addition site in the pLAT3.3 plasmid, which nonetheless
promoted cell survival, and the lack of obvious poly(A) addition sites
within the insertion site in the LAT3.3A virus, which nonetheless
reactivates efficiently from latency, appear to support the hypothesis
that a LAT protein is not expressed. If a LAT protein does not exist,
it would appear that LAT RNA sequences promote cell survival.
Approximately 90% of steady-state LAT (i.e., the stable 2-kb LAT) is
localized in the nucleus (50, 56). Only 10% of LAT is
found in the cytoplasm, some of which appears to be associated with
polyribosomes (24). At first glance, this appears to be inconsistent with the ability of LAT to block apoptosis, as this function might be thought of as requiring a LAT product in the cytoplasm. Even if LAT were exclusively limited to the nucleus, it
could inhibit apoptosis by regulating transcription of one or more
cellular genes. The stable 2-kb LAT represents the overwhelming majority of LAT that is detected during acute and latent infection, suggesting that if other novel forms of LAT were expressed, they would
be difficult to detect. Thus, studies indicating that LAT is localized
in the nucleus are essentially referring to the 2-kb LAT. As discussed
above, the stable 2-kb LAT is not required either for wild-type levels
of spontaneous reactivation or for blocking apoptosis. These functions
can both be accomplished by just the first 1.5 kb of the primary LAT, a
fragment that includes only the first 838 nucleotides of the 2-kb LAT.
This truncated LAT lacks the stability of the 2-kb LAT, and its
subcellular location is unknown. Thus, it will be of interest to
elucidate the structure and subcellular localization of transcripts
that are expressed by LAT sequences which are capable of inhibiting
apoptosis. Studies directed at pinpointing the sequences in LAT that
interfere with apoptosis and identification of cellular components
affected by LAT will be pursued.
| |
ACKNOWLEDGMENTS |
Melissa Inman and Guey-Chuen Perng contributed equally to this study.
We thank Rick Thompson (U. of Cincinnati Med. Ctr.) for providing the
APALAT plasmid.
This study was supported by the Center for Biotechnology (UNL), the
Comparative Pathobiology Area of Concentration, the Discovery Fund for
Eye Research, the Skirball Program in Molecular Ophthalmology, and
Public Health Service grants to S.L.W. (EY07566, EY11629, and EY12823)
and C.J. (1P20RR15635).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dept. of
Veterinary and Biomedical Sciences, University of Nebraska, Lincoln,
Fair Street at East Campus Loop, Lincoln, NE 68583-0905, Phone: (402) 472-1890. Fax: (402) 472-9690. E-mail:
cjones{at}unlnotes.unl.edu.
| |
REFERENCES |
| 1.
|
Asano, S.,
T. Honda,
F. Goshima,
D. Watanabe,
Y. Miyake,
Y. Sugiura, and Y. Nishiyama.
1999.
US3 protein kinase of herpes simplex virus type 2 plays a role in protecting corneal epithelial cells from apoptosis in infected mice.
J. Gen. Virol.
80:51-56[Abstract].
|
| 2.
|
Aubert, M., and J. A. Blaho.
1999.
The herpes simplex virus type 1 regulatory protein ICP27 is required for the prevention of apoptosis in infected human cells.
J. Virol.
73:2803-2813[Abstract/Free Full Text].
|
| 3.
|
Baringer, J. R., and P. Swoveland.
1973.
Recovery of herpes simplex virus from human trigeminal ganglions.
N. Engl. J. Med.
288:648-650.
|
| 4.
|
Bastian, F. O.,
A. S. Rabson,
C. L. Yee, and T. S. Tralka.
1972.
Herpesvirus hominis: isolation from human trigeminal ganglion.
Science
178:306-307[Abstract/Free Full Text].
|
| 5.
|
Bernhard, D.,
M. J. Ausserlechner,
M. Tonko,
M. Loffler,
B. L. Hartmann,
A. Csordas, and R. Kofler.
1999.
Apoptosis induced by the histone deacetylase inhibitor sodium butyrate in human leukemic lymphoblasts.
FASEB J.
13:1991-2001[Abstract/Free Full Text].
|
| 6.
|
Boesen-de Cock, J. G.,
A. D. Tepper,
E. de Vries,
W. J. van Blitterswijk, and J. Borst.
1999.
Common regulation of apoptosis signaling induced by CD95 and the DNA-damaging stimuli etoposide and gamma-radiation downstream from caspase-8 activation.
J. Biol. Chem.
274:14255-14261[Abstract/Free Full Text].
|
| 7.
|
Busser, J.,
D. S. Geldmacher, and K. Herrup.
1998.
Ectopic cell cycle proteins predict the sites of neuronal cell death in Alzheimer's disease brain.
J. Neurosci.
18:2801-2807[Abstract/Free Full Text].
|
| 8.
|
Chen, S. H.,
M. F. Kramer,
P. A. Schaffer, and D. M. Coen.
1997.
A viral function represses accumulation of transcripts from productive-cycle genes in mouse ganglia latently infected with herpes simplex virus.
J. Virol.
71:5878-5884[Abstract].
|
| 9.
|
Ciacci-Zanella, J.,
M. Stone,
G. Henderson, and C. Jones.
1999.
The latency-related gene of bovine herpesvirus 1 inhibits programmed cell death.
J. Virol.
73:9734-9740[Abstract/Free Full Text].
|
| 10.
|
Ciacci-Zanella, J. R., and C. Jones.
1999.
Fumonisin B1, a mycotoxin contaminant of cereal grains, and inducer of apoptosis via the tumour necrosis factor pathway and caspase activation.
Food Chem. Toxicol.
37:703-712[CrossRef][Medline].
|
| 11.
|
Deatly, A. M.,
J. G. Spivack,
E. Lavi, and N. W. Fraser.
1987.
RNA from an immediate early region of the type 1 herpes simplex virus genome is present in the trigeminal ganglia of latently infected mice.
Proc. Natl. Acad. Sci. USA
84:3204-3208[Abstract/Free Full Text].
|
| 12.
|
Deatly, A. M.,
J. G. Spivack,
E. Lavi,
D. R. O'Boyle, 3rd, and N. W. Fraser.
1988.
Latent herpes simplex virus type 1 transcripts in peripheral and central nervous system tissues of mice map to similar regions of the viral genome.
J. Virol.
62:749-756[Abstract/Free Full Text].
|
| 13.
|
Devireddy, L. R., and C. J. Jones.
1999.
Activation of caspases and p53 by bovine herpesvirus 1 infection results in programmed cell death and efficient virus release.
J. Virol.
73:3778-3788[Abstract/Free Full Text].
|
| 14.
|
Devireddy, L. R., and C. J. Jones.
2000.
Olf-1, a neuron-specific transcription factor, can activate the herpes simplex virus type 1-infected cell protein 0 promoter.
J. Biol. Chem.
275:77-81[Abstract/Free Full Text].
|
| 15.
|
Drolet, B. S.,
G. C. Perng,
J. Cohen,
S. M. Slanina,
A. Yukht,
A. B. Nesburn, and S. L. Wechsler.
1998.
The region of the herpes simplex virus type 1 LAT gene involved in spontaneous reactivation does not encode a functional protein.
Virology
242:221-232[CrossRef][Medline].
|
| 16.
|
Drolet, B. S.,
G. C. Perng,
R. J. Villosis,
S. M. Slanina,
A. B. Nesburn, and S. L. Wechsler.
1999.
Expression of the first 811 nucleotides of the herpes simplex virus type 1 latency-associated transcript (LAT) partially restores wild-type spontaneous reactivation to a LAT-null mutant.
Virology
253:96-106[CrossRef][Medline].
|
| 17.
|
Farrell, M. J.,
A. T. Dobson, and L. T. Feldman.
1991.
Herpes simplex virus latency-associated transcript is a stable intron.
Proc. Natl. Acad. Sci. USA
88:790-794[Abstract/Free Full Text].
|
| 18.
|
Galvan, V.,
R. Brandimarti, and B. Roizman.
1999.
Herpes simplex virus 1 blocks caspase-3-independent and caspase- dependent pathways to cell death.
J. Virol.
73:3219-3226[Abstract/Free Full Text].
|
| 19.
|
Galvan, V., and B. Roizman.
1998.
Herpes simplex virus 1 induces and blocks apoptosis at multiple steps during infection and protects cells from exogenous inducers in a cell-type-dependent manner.
Proc. Natl. Acad. Sci. USA
95:3931-3936[Abstract/Free Full Text].
|
| 20.
|
Garber, D. A.,
P. A. Schaffer, and D. M. Knipe.
1997.
A LAT-associated function reduces productive-cycle gene expression during acute infection of murine sensory neurons with herpes simplex virus type 1.
J. Virol.
71:5885-5893[Abstract].
|
| 21.
|
Gill, J. S., and A. J. Windebank.
1998.
Cisplatin-induced apoptosis in rat dorsal root ganglion neurons is associated with attempted entry into the cell cycle.
J. Clin. Investig.
101:2842-2850[Medline].
|
| 22.
|
Giuliano, M.,
M. Lauricella,
G. Calvaruso,
M. Carabillo,
S. Emanuele,
R. Vento, and G. Tesoriere.
1999.
The apoptotic effects and synergistic interaction of sodium butyrate and MG132 in human retinoblastoma Y79 cells.
Cancer Res.
59:5586-5595[Abstract/Free Full Text].
|
| 23.
|
Gobbel, G. T.,
M. Bellinzona,
A. R. Vogt,
N. Gupta,
J. R. Fike, and P. H. Chan.
1998.
Response of postmitotic neurons to X-irradiation: implications for the role of DNA damage in neuronal apoptosis.
J. Neurosci.
18:147-155[Abstract/Free Full Text].
|
| 24.
|
Goldenberg, D.,
N. Mador,
M. J. Ball,
A. Panet, and I. Steiner.
1997.
The abundant latency-associated transcripts of herpes simplex virus type 1 are bound to polyribosomes in cultured neuronal cells and during latent infection in mouse trigeminal ganglia.
J. Virol.
71:2897-2904[Abstract].
|
| 25.
|
Hsu, H.,
J. Xiong, and D. V. Goeddel.
1995.
The TNF receptor 1-associated protein TRADD signals cell death and NF- B activation.
Cell
81:495-504[CrossRef][Medline].
|
| 26.
|
Hu, S.,
P. K. Peterson, and C. C. Chao.
1997.
Cytokine-mediated neuronal apoptosis.
Neurochem. Int.
30:427-431[CrossRef][Medline].
|
| 27.
|
Jones, C.
1998.
Alphaherpesvirus latency: its role in disease and survival of the virus in nature.
Adv. Virus Res.
51:81-133[Medline].
|
| 28.
|
Jones, C.,
G. Delhon,
A. Bratanich,
G. Kutish, and D. Rock.
1990.
Analysis of the transcriptional promoter which regulates the latency-related transcript of bovine herpesvirus 1.
J. Virol.
64:1164-1170[Abstract/Free Full Text].
|
| 29.
|
Knotts, F. B.,
M. L. Cook, and J. G. Stevens.
1974.
Pathogenesis of herpetic encephalitis in mice after ophthalmic inoculation.
J. Infect. Dis.
130:16-27[Medline].
|
| 30.
|
Kramer, M. F.,
S. H. Chen,
D. M. Knipe, and D. M. Coen.
1998.
Accumulation of viral transcripts and DNA during establishment of latency by herpes simplex virus.
J. Virol.
72:1177-1185[Abstract/Free Full Text].
|
| 31.
|
Kramer, M. F., and D. M. Coen.
1995.
Quantification of transcripts from the ICP4 and thymidine kinase genes in mouse ganglia latently infected with herpes simplex virus.
J. Virol.
69:1389-1399[Abstract].
|
| 32.
|
Krause, P. R.,
K. D. Croen,
S. E. Straus, and J. M. Ostrove.
1988.
Detection and preliminary characterization of herpes simplex virus type 1 transcripts in latently infected human trigeminal ganglia.
J. Virol.
62:4819-4823[Abstract/Free Full Text].
|
| 33.
|
Krummenacher, C.,
J. M. Zabolotny, and N. W. Fraser.
1997.
Selection of a nonconsensus branch point is influenced by an RNA stem-loop structure and is important to confer stability to the herpes simplex virus 2-kilobase latency-associated transcript.
J. Virol.
71:5849-5860[Abstract].
|
| 34.
|
Kumar, S.,
M. Kinoshita,
M. Noda,
N. G. Copeland, and N. A. Jenkins.
1994.
Induction of apoptosis by the mouse Nedd2 gene, which encodes a protein similar to the product of the Caenorhabditis elegans cell death gene ced-3 and the mammalian IL-1 beta-converting enzyme.
Genes Dev.
8:1613-1626[Abstract/Free Full Text].
|
| 35.
|
Le-Niculescu, H.,
E. Bonfoco,
Y. Kasuya,
F. X. Claret,
D. R. Green, and M. Karin.
1999.
Withdrawal of survival factors results in activation of the JNK pathway in neuronal cells leading to Fas ligand induction and cell death.
Mol. Cell. Biol.
19:751-763[Abstract/Free Full Text].
|
| 36.
|
Leopardi, R., and B. Roizman.
1996.
The herpes simplex virus major regulatory protein ICP4 blocks apoptosis induced by the virus or by hyperthermia.
Proc. Natl. Acad. Sci. USA
93:9583-9587[Abstract/Free Full Text].
|
| 37.
|
Nip, J.,
D. K. Strom,
B. E. Fee,
G. Zambetti,
J. L. Cleveland, and S. W. Hiebert.
1997.
E2F-1 cooperates with topoisomerase II inhibition and DNA damage to selectively augment p53-independent apoptosis.
Mol. Cell. Biol.
17:1049-1056[Abstract].
|
| 38.
|
Park, D. S.,
S. E. Farinelli, and L. A. Greene.
1996.
Inhibitors of cyclin-dependent kinases promote survival of post-mitotic neuronally differentiated PC12 cells and sympathetic neurons.
J. Biol. Chem.
271:8161-8169[Abstract/Free Full Text].
|
| 39.
|
Park, D. S.,
B. Levine,
G. Ferrari, and L. A. Greene.
1997.
Cyclin dependent kinase inhibitors and dominant negative cyclin dependent kinase 4 and 6 promote survival of NGF-deprived sympathetic neurons.
J. Neurosci.
17:8975-8983[Abstract/Free Full Text].
|
| 40.
|
Park, D. S.,
E. J. Morris,
L. Stefanis,
C. M. Troy,
M. L. Shelanski,
H. M. Geller, and L. A. Greene.
1998.
Multiple pathways of neuronal death induced by DNA-damaging agents, NGF deprivation, and oxidative stress.
J. Neurosci.
18:830-840[Abstract/Free Full Text].
|
| 41.
|
Pawlowski, J., and A. S. Kraft.
2000.
Bax-induced apoptotic cell death.
Proc. Natl. Acad. Sci.
97:529-531[Free Full Text].
|
| 42.
|
Perng, G.-C.,
C. Jones,
J. Ciacci-Zanella,
M. Stone,
G. Henderson,
A. Yukht,
S. M. Slanina,
F. M. Hoffman,
H. Ghiasi,
A. B. Nesburn, and S. Wechsler.
2000.
Virus-induced neuronal apoptosis blocked by the herpes simplex virus latency-associated transcript (LAT).
Science
287:1500-1503[Abstract/Free Full Text].
|
| 43.
|
Perng, G.-C.,
K. Chokephaibulkit,
R. L. Thompson,
N. M. Sawtell,
S. M. Slanina,
H. Ghiasi,
A. B. Nesburn, and S. L. Wechsler.
1996.
The region of the herpes simplex virus type 1 LAT gene that is colinear with the ICP34.5 gene is not involved in spontaneous reactivation.
J. Virol.
70:282-291[Abstract].
|
| 44.
|
Perng, G.-C.,
E. C. Dunkel,
P. A. Geary,
S. M. Slanina,
H. Ghiasi,
R. Kaiwar,
A. B. Nesburn, and S. L. Wechsler.
1994.
The latency-associated transcript gene of herpes simplex virus type 1 (HSV-1) is required for efficient in vivo spontaneous reactivation of HSV-1 from latency.
J. Virol.
68:8045-8055[Abstract/Free Full Text].
|
| 45.
|
Perng, G.-C.,
H. Ghiasi,
S. M. Slanina,
A. B. Nesburn, and S. L. Wechsler.
1996.
The spontaneous reactivation function of the herpes simplex virus type 1 LAT gene resides completely within the first 1.5 kilobases of the 8.3-kilobase primary transcript.
J. Virol.
70:976-984[Abstract].
|
| 46.
|
Perng, G.-C.,
S. M. Slanina,
H. Ghiasi,
A. B. Nesburn, and S. L. Wechsler.
1996.
A 371-nucleotide region between the herpes simplex virus type 1 (HSV-1) LAT promoter and the 2-kilobase LAT is not essential for efficient spontaneous reactivation of latent HSV-1.
J. Virol.
70:2014-2018[Abstract].
|
| 47.
|
Perng, G.-C.,
S. M. Slanina,
A. Yukht,
H. Ghiasi,
A. B. Nesburn, and S. L. Wechsler.
2000.
The latency-associated transcript gene enhances establishment of herpes simplex virus type 1 latency in rabbits.
J. Virol.
74:1885-1891[Abstract/Free Full Text].
|
| 48.
|
Rock, D. L.,
A. B. Nesburn,
H. Ghiasi,
J. Ong,
T. L. Lewis,
J. R. Lokensgard, and S. L. Wechsler.
1987.
Detection of latency-related viral RNAs in trigeminal ganglia of rabbits latently infected with herpes simplex virus type 1.
J. Virol.
61:3820-3826[Abstract/Free Full Text].
|
| 49.
|
Soldatenkov, V. A.,
S. Prasad,
Y. Voloshin, and A. Dritschilo.
1998.
Sodium butyrate induces apoptosis and accumulation of ubiquitinated proteins in human breast carcinoma cells.
Cell Death Differ.
5:307-312[CrossRef][Medline].
|
| 50.
|
Speck, P. G., and A. Simmons.
1991.
Divergent molecular pathways of productive and latent infection with a virulent strain of herpes simplex virus type 1.
J. Virol.
65:4001-4005[Abstract/Free Full Text].
|
| 51.
|
Stevens, J. G.,
E. K. Wagner,
G. B. Devi-Rao,
M. L. Cook, and L. T. Feldman.
1987.
RNA complementary to a herpesvirus alpha gene mRNA is prominent in latently infected neurons.
Science
235:1056-1059[Abstract/Free Full Text].
|
| 52.
|
Wagner, E. K., and D. C. Bloom.
1997.
Experimental investigation of herpes simplex virus latency.
Clin. Microbiol. Rev.
10:419-443[Abstract].
|
| 53.
|
Wagner, E. K.,
W. M. Flanagan,
G. Devi-Rao,
Y. F. Zhang,
J. M. Hill,
K. P. Anderson, and J. G. Stevens.
1988.
The herpes simplex virus latency-associated transcript is spliced during the latent phase of infection.
J. Virol.
62:4577-4585[Abstract/Free Full Text].
|
| 54.
|
Wechsler, S. L.,
A. B. Nesburn,
R. Watson,
S. Slanina, and H. Ghiasi.
1988.
Fine mapping of the major latency-related RNA of herpes simplex virus type 1 in humans.
J. Gen. Virol.
69:3101-3106[Abstract/Free Full Text].
|
| 55.
|
White, E.
1996.
Life, death, and the pursuit of apoptosis.
Genes Dev.
10:1-15[Free Full Text].
|
| 56.
|
Zwaagstra, J. C.,
H. Ghiasi,
S. M. Slanina,
A. B. Nesburn,
S. C. Wheatley,
K. Lillycrop,
J. Wood,
D. S. Latchman,
K. Patel, and S. L. Wechsler.
1990.
Activity of herpes simplex virus type 1 latency-associated transcript (LAT) promoter in neuron-derived cells: evidence for neuron specificity and for a large LAT transcript.
J. Virol.
64:5019-5028[Abstract/Free Full Text].
|
Journal of Virology, April 2001, p. 3636-3646, Vol. 75, No. 8
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.8.3636-3646.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
