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Journal of Virology, November 1999, p. 8950-8957, Vol. 73, No. 11
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Herpes Simplex Virus Inhibits Apoptosis through
the Action of Two Genes, Us5 and Us3
Keith R.
Jerome,1,3,*
Richard
Fox,1
Zheng
Chen,1
Amy E.
Sears,2
Hyung-yul
Lee,2 and
Lawrence
Corey1,3
Department of Laboratory Medicine, University
of Washington, Seattle, Washington 98195,1
Program in Infectious Diseases, Department of Microbiology and
Immunology, Emory University, Atlanta, Georgia
30322,2 and Fred Hutchinson Cancer
Research Center, Seattle, Washington 981043
Received 6 April 1999/Accepted 20 July 1999
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ABSTRACT |
Apoptosis of virus-infected cells occurs either as a direct
response to viral infection or upon recognition of infection by the
host immune response. Apoptosis reduces production of new virus from
these cells, and therefore viruses have evolved inhibitory mechanisms.
We previously showed that laboratory strains of herpes simplex virus
type 1 (HSV-1) protect infected cells from apoptosis induced by
cytotoxic T lymphocytes or ethanol. We have now evaluated the ability
of HSV-1 and HSV-2 laboratory and clinical isolates to inhibit
apoptosis induced by anti-Fas antibody or UV irradiation and explored
the genetic basis for this inhibition. HSV-1 isolates inhibited
apoptosis induced by UV or anti-Fas antibody. In contrast, HSV-2
clinical isolates failed to inhibit apoptosis induced by either
stimulus, although the HSV-2 laboratory strain 333 had a partial
inhibitory effect on UV-induced apoptosis. Inhibition of apoptosis by
HSV was accompanied by marked reduction of caspase-3 and caspase-8
activity. Deletion of the HSV-1 Us3 gene markedly reduced inhibition of
UV-induced apoptosis and partially abrogated inhibition of Fas-mediated
apoptosis. Conversely, deletion of the HSV-1 Us5 gene markedly reduced
protection from Fas-mediated apoptosis and partially abrogated
protection from UV. The Us11 and Us12 genes were not necessary for
protection from apoptosis induced by either stimulus. The differences
between HSV-1 and HSV-2 in the ability to inhibit apoptosis may be
factors in the immunobiology of HSV infections.
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INTRODUCTION |
Successful viruses use multiple
mechanisms to alter host cell functions to their advantage. For
example, the herpes simplex viruses (HSVs) have evolved mechanisms to
inhibit host cell death, or apoptosis. Recently we have demonstrated
that HSV type 1 (HSV-1) infection protects target cells from cytotoxic
T-lymphocyte (CTL)-induced apoptosis (16). This phenomenon
is intuitively beneficial to the virus in that it may protect infected
cells from attack by the immune system.
It has been suggested that programmed cell death may have first evolved
in unicellular organisms as a primitive population immune system, in
which cells infected with a virus would activate their death programs,
thus protecting other members of the population (31, 36). In
a similar manner, individual cells in multicellular organisms often
respond to viral infection by undergoing apoptosis, thus protecting
other cells of the organism from infection (32). In addition
to our work with CTL-induced apoptosis, Leopardi et al. have shown that
HSV-1 can protect cells from apoptosis induced by the virus, through
the action of the Us3 gene (19). This presumably allows
infected cells to survive long enough to support viral replication.
Recent reports have suggested that viruses may selectively inhibit some
but not all portions of the apoptotic machinery. For example, equine
herpes virus 8 and molluscum contagiosum virus inhibit apoptosis
induced via the Fas receptor, by encoding gene products containing a
nonfunctional death domain which interacts with Fas-associated death
domain protein (FADD) (6, 33). However, these genes are
unable to inhibit apoptosis induced by UV radiation (6).
Along similar lines, we have recently shown that HSV-1 inhibits the
nuclear events of ethanol-induced apoptosis, such as DNA fragmentation,
but has no effect on phosphatidylserine externalization at the cell
membrane (16). In contrast, HSV-2 showed no antiapoptotic
activity under these conditions.
As a corollary to differences in their relative inhibition of various
manifestations of apoptosis, some viruses have evolved multiple
apoptosis-inhibitory mechanisms. Herpesviruses, being large, are good
candidates to have multiple antiapoptosis genes (5, 32). It
has been previously reported that the Us3 gene of HSV-1 is required to
inhibit apoptosis induced by the virus (19). However, in our
hands, viruses deleted for Us3 retained some antiapoptotic activity.
These findings led us to investigate whether HSV-1 encodes additional
genes which inhibit apoptosis and whether HSV-2 can also inhibit
apoptosis induced by some stimuli. In this report, we demonstrate that
HSV-1 encodes at least two antiapoptotic genes, Us5 and Us3, which
strongly inhibit apoptosis induced via the Fas receptor or UV
radiation. In contrast, at least one HSV-2 strain may modestly inhibit
apoptosis induced by UV but does not inhibit apoptosis induced by Fas
ligation. Using virus strains with deletions in the HSV-1 genes Us5 and Us3, we demonstrated that these genes cooperate to inhibit apoptosis. The evolution of two HSV genes which inhibit apoptosis suggests that
this is an important function for the virus and thus may play a role in
the biology and transmission efficiencies of HSV-1 and HSV-2.
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MATERIALS AND METHODS |
Cell lines.
Vero and Jurkat cells were obtained from the
American Type Culture Collection (Manassas, Va.). Cell lines were
screened for mycoplasma contamination in an in situ hybridization assay
(Geneprobe, San Diego, Calif.).
Viruses.
Clinical isolates of HSV-1 (F28700, H61146, and
M36562) and HSV-2 (F43031 and T75419) were obtained from the University
of Washington diagnostic virology laboratory. Laboratory strains were
E115 (HSV-1) and 333 (HSV-2). Viral stocks were grown in Vero cells,
and titers were determined by standard plaque assays. The Us3 deletion
and rescue viruses, R7041 and 7306, were a gift from Bernard Roizman
(26). The Us5 deletion and rescue viruses, RAS116 and
RAS137, are described elsewhere (30).
Morphological assay using acridine orange and ethidium
bromide.
Morphological changes of apoptosis were observed by
ethidium bromide-acridine orange staining and fluorescence microscopy (Zeiss model 9901). Jurkat cells were split into log phase growth and
incubated at 37°C for 12 h. Cells were then infected with virus
at 10 PFU/cell, or mock infected, and incubated at 37°C for 5 h.
Infected cells were induced into apoptosis by either UV light (30-W UV
bulb at 20 cm for 30 s) or anti-Fas antibody APO-1-3 (Alexis, San
Diego, Calif.) or CH-11 (Tanvera, Madison, Wis.) at 1,000 ng/ml and
incubated at 37C for 4 h. In general, antibody CH-11 induced
apoptosis more strongly than did APO-1-3. A minimum of 200 cells were
counted from each sample by a blinded observer and categorized into one
of three groups by morphological characteristics: live (cells showing
no characteristics of apoptosis), apoptotic (cells showing shrinkage,
membrane blebbing, and/or nuclear fragmentation), or necrotic (cells
that did not show apoptotic morphology but allowed entry of ethidium
bromide). Results were analyzed with the two-tailed Student's
t test, using the statistical package in Microsoft Excel
(Microsoft Corp., Redmond, Wash.), and are presented as mean and
standard error of the mean (SEM).
Fluorometric assay for caspase-3 or caspase-8 activation.
Jurkat cells (106) were infected with HSV at 10 PFU/cell or
mock infected and incubated at 37°C for 5 h. Cells were then
induced into apoptosis with UV irradiation or anti-Fas antibody and
incubated for 4 h at 37°C. The cells were harvested, and lysates
were evaluated for caspase activity by using ApoAlert caspase-3 and
caspase-8 assay kits (Clontech, Palo Alto, Calif.) according to the
manufacturer's instructions. Fluorescence was measured at 0, 30, and
60 min after addition of substrate on a CytoFluor II fluorescence plate
reader (PerSeptive Biosystems, Framingham, Mass.). To allow comparison between separate experiments which may have different maximal relative
fluorescence unit (RFU) measurements, the RFU value for control
(uninfected) cells induced into apoptosis as measured at 60 min was
converted to a relative activity value of 100, and other RFU values
within the same experiment were normalized to obtain a relative
(percent) activity. Results were analyzed with the two-tailed
Student's t test, using the statistical package in
Microsoft Excel.
Effect of apoptosis on viral titer.
Jurkat cells were split
into log-phase growth overnight and then infected with HSV at an 5 PFU/cell; 2 or 5 h later the cells were exposed to UV as described
above and incubated at 37°C. Virus was harvested from the cells at
various time points by sonication, and yield was determined in a
standard plaque assay.
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RESULTS |
Effects of isolates of HSV-1 and HSV-2 on UV-induced
apoptosis.
We previously showed that infection with laboratory
strains of HSV-1 rendered cells resistant to apoptosis induced by
either ethanol or CTL (16). Because CTL use multiple
pathways to induce apoptosis in their targets, we investigated the
ability of HSV-1 to inhibit apoptosis induced by the Fas receptor, a
well-defined pathway involved in both CTL killing and immune regulation
(12). To determine whether the ability of HSV-1 to inhibit
apoptosis varies depending on the inducing stimulus, we also examined
the ability of HSV-1 to inhibit apoptosis induced by UV irradiation. UV-induced apoptosis is mediated in part by a p53-dependent mechanism (13, 35) and partially through other pathways (1,
34). To confirm that our previous findings for laboratory strains
of HSV were generally applicable to field strains, we also used several low (three or fewer)-passage clinical isolates.
Jurkat cells were infected with an isolate of HSV-1 or mock infected
and then incubated for 5 h to allow full expression of the
antiapoptotic effect (16). The cells were then UV or mock treated and incubated 4 h before morphologic evaluation by a
blinded observer. A representative experiment is shown in Fig.
1.
Uninfected, UV-irradiated cells showed clear apoptotic morphology, with
markedly shrunken and fragmented nuclei (Fig. 1B). In contrast, cells
which were preinfected with a clinical isolate of HSV-1 (strain H61146) were markedly protected from UV-induced apoptosis (Fig. 1C) and had a
morphology almost indistinguishable from that of cells which had been
left untreated (Fig. 1A). In a blinded manner, cells with healthy,
apoptotic, or necrotic morphology were counted in a hemacytometer,
which allowed quantification of the antiapoptotic effect of each HSV-1
strain (Fig. 1D). Both the laboratory strain E115 and the clinical
isolate F28700 showed strong inhibition of UV-induced apoptosis
(P < 0.002 and <0.001, respectively). In contrast,
inactivated virus failed to inhibit apoptosis.
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FIG. 1.
Clinical and laboratory strains of HSV-1 and HSV-2
inhibit UV-induced apoptosis. Jurkat cells were mock or HSV infected
for 5 h prior to induction of apoptosis with UV radiation. The
morphological changes of apoptosis were assessed by a blinded observer
using fluorescence microscopy. (A) Uninfected cells without UV
irradiation; (B) uninfected cells after UV irradiation; (C)
HSV-1-infected cells (strain H61146) after treatment with UV; (D and E)
percent apoptosis after infection with a clinical (F28700, F43031, and
T75419) or laboratory (E115 and 333) strains of HSV-1 (D) and HSV-2
(E). Shown is mean + SEM of two to five independent experiments.
In some instances, error bars are too small to be seen.
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We next tested the ability of strains of HSV-2 to inhibit UV-induced
apoptosis. We previously showed that HSV-2 failed to
inhibit apoptosis
induced by CTL or ethanol (
16). In agreement
with those
results, the clinical isolates of HSV-2 did not show
an inhibitory
effect on UV-induced apoptosis (Fig.
1E). The laboratory
HSV-2 strain
333 appeared to show a modest inhibitory effect;
however, this did not
reach statistical
significance.
Effects of clinical isolates of HSV-1 and HSV-2 on Fas-mediated
apoptosis.
Because our previous studies demonstrated that
laboratory strains of HSV-1, but not HSV-2, could inhibit apoptosis
induced by CTL (16), we examined whether clinical or
laboratory isolates of these viruses might inhibit apoptosis mediated
through the Fas receptor. The interaction of Fas ligand on CTL with the
Fas receptor on target cells is one of the mechanisms by which CTL induce apoptosis in their targets and is especially important in immune
regulation. Consistent with our previous results with CTL-induced
apoptosis, strains of HSV-1 showed inhibition of Fas-mediated apoptosis
(Fig. 2A, P < 0.01).
Again, the antiapoptotic ability was lost after inactivation of virus.
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FIG. 2.
Strains of HSV-1, but not HSV-2, inhibit Fas-mediated
apoptosis. Percent apoptosis by anti-Fas antibody APO-1-3 after
infection with clinical (F28700, F43031, and T75419) or laboratory
(E115 and 333) strains of HSV-1 (A) or HSV-2 (B), as determined by a
blinded observer using fluorescence microscopy. Shown is mean + SEM of two to five independent experiments. In some instances, error
bars are too small to be seen.
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In contrast to the inhibition seen with HSV-1, none of the HSV-2
strains were able to inhibit Fas-mediated apoptosis (Fig.
2B). Even the
laboratory strain 333, which showed a possible modest
inhibitory effect
on UV-induced apoptosis, failed to inhibit Fas-mediated
apoptosis.
Although HSV-1 protected Jurkat cells from apoptosis at 4 h after
treatment with anti-Fas, many previous studies of Fas-mediated
cell
death in Jurkat cells have used longer incubation times (typically
12 h) to allow full expression of Fas-mediated apoptosis. We
therefore
performed a time course experiment to evaluate whether HSV
could
protect Jurkat cells from Fas-mediated death at these later time
points. Jurkat cells were mock or HSV-1 infected and 5 h later
induced into apoptosis with anti-Fas antibody CH11. Protection
from
apoptosis was then determined 4, 8, and 12 h after addition
of
anti-Fas antibody (Fig.
3). Even 12 h posttreatment, HSV-1-infected
cells were markedly (>50%) protected
from Fas-mediated cell death.
The degree of protection was stronger at
early time points and
decreased somewhat over time, in agreement with
our earlier observation
that HSV-1 protection from
anti-Fas-antibody-induced apoptosis
is not necessarily complete.
Nevertheless, even at relatively
late time points, HSV-1 still strongly
protected cells from Fas-mediated
death. We evaluated the cultures at a
still later time point (24
h after addition of anti-Fas), but extensive
viral cytopathic
effect in the infected cells precluded evaluation of
apoptosis.
These observations are consistent with our hypothesis that
HSV-1
need only inhibit (or delay) apoptosis until the viral
replication
cycle can complete.
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FIG. 3.
Time course of HSV inhibition of Fas-mediated apoptosis.
Jurkat cells were mock or HSV-1 infected, incubated for 5 h, and
treated with 1,000 ng of anti-Fas antibody CH11 per ml. Apoptosis was
evaluated at the indicated times after anti-Fas treatment by a blinded
observer using fluorescence microscopy. Cells could not be evaluated at
24 h due to extensive viral cytopathic effect. Shown is mean of
two independent experiments.
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Inhibition of caspase activation by HSV-1 and HSV-2.
Morphologic examination of cells for apoptosis by a blinded observer is
a well accepted and reproducible method of evaluating apoptosis
(22), but it provides limited insights into the mechanisms by which inhibition of apoptosis might occur. We therefore investigated whether HSV infection resulted in inhibition of caspase activation during apoptosis. Caspases are cytoplasmic proteins which normally exist in an inactive proenzyme form (20). Upon cleavage,
typically by another caspase or apoptosis regulatory protein, caspases
are activated and cleave downstream caspases or other apoptotic
proteins. Infection with HSV-1 inhibited the activation of caspase-3 by 70 to 75% after UV induction of apoptosis (Fig.
4, P < 0.001). Caspase-3
activation after Fas ligation was also inhibited by HSV-1, although
only 30 to 35% (Fig. 4, P < 0.002). Similarly, HSV-1
inhibited caspase-8 (FLICE) activation about 70% after UV treatment
(P = 0.003) and 30% after Fas ligation (P < 0.001). HSV-1 infection alone did not result in activation of
caspases (not shown) and in fact led to a consistent slight decrease in the level of background caspase-3 and caspase-8 activity. These findings are in agreement with the substantial inhibition of the morphologic changes of apoptosis after infection with HSV-1 and the
apparently stronger inhibition of UV- than Fas-mediated apoptosis.
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FIG. 4.
Inhibition of caspase activity after UV or anti-Fas
treatment by HSV-1 and HSV-2. Jurkat cells were mock or HSV infected
for 5 h prior to induction of apoptosis with UV radiation or
anti-Fas antibody. Caspase-3 (-8) or caspase-8 (-8) activity was
measured in cell lysates made 4 h later. Virus infection alone
with HSV-1 or HSV-2 did not lead to caspase-3 or caspase-8 activation
(not shown). Shown is mean ± SEM of from two to five independent
experiments. In some instances, error bars are too small to be seen.
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In agreement with their inability to inhibit the morphologic changes of
apoptosis, none of the clinical isolates of HSV-2
showed any inhibitory
effect on caspase-3 or caspase-8 activation
after apoptosis induction
by UV or anti-Fas (Fig.
4). Again, infection
with HSV-2 alone did not
lead to activation of caspase-3 or caspase-8
(not shown). The HSV-2
laboratory strain 333 also failed to show
inhibition of caspase
activation after Fas ligation. However,
333 behaved differently after
UV induction of apoptosis, showing
inhibitory activity against both
caspase-3 and caspase-8 (Fig.
4). Caspase-3 activity after UV was
inhibited 50 to 60% (
P = 0.01),
while caspase-8
activity was inhibited 70 to 80% (
P < 0.05). Again,
this finding is in agreement with the modest inhibition of the
morphologic changes of apoptosis seen with strain
333.
The HSV-1 genes Us3 and Us5 are required for the antiapoptotic
effect.
To investigate the mechanisms used by the virus to inhibit
apoptosis, we used mutant virus with deletions of individual
antiapoptosis genes. The HSV-1 gene Us3 encodes a serine/threonine
kinase which has been shown to prevent apoptosis from occurring as a
direct result of viral infection (19). To determine whether
this gene could also function to protect infected cells from apoptosis
induced by other stimuli, we infected Jurkat cells with either a mutant HSV-1 containing a deletion of Us3 (R7041) or the Us3 rescue virus R7306. R7306 has had the Us3 gene restored and thus would be expected to behave as wild-type virus. Inclusion of rescue virus controls are
important to exclude possible second mutations in deletion viruses
(19). Deletion of Us3 (R7041) completely abrogated the ability of the virus to prevent apoptosis induced by UV (Fig. 5B) and
greatly reduced its ability to inhibit apoptosis induced by Fas
ligation (Fig. 5A).
The rescue virus, R7306, which has had Us3 function restored (19), regained full inhibitory
activity after either stimulus. These results suggest that the Us3 gene product not only inhibits apoptosis induced by the virus but also contributes to protection from UV- or anti-Fas-induced apoptosis. However, the partial protection from Fas-induced apoptosis even by the
Us3 deletion virus suggested that additional antiapoptosis genes might
be present.
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FIG. 5.
Inhibition of Fas-mediated or UV-induced apoptosis by
deletion mutants of HSV-1. Jurkat cells were infected with the
indicated mutant virus at 10 PFU/cell for 5 h, and apoptosis was
induced by anti-Fas antibody (A, C, and E) or UV irradiation (B, D, and
F). Open bars, untreated cells; shaded bars, treated cells. Percent
apoptosis was determined by a blinded observer using fluorescence
microscopy. Shown is the mean + SEM of two to four independent
experiments. (G to J) Inhibition of caspase activity by HSV-1 deletion
mutant RAS116 ( ) and rescue mutant RAS137 ( ). Jurkat cells were
mock infected ( ) or HSV infected for 5 h prior to induction of
apoptosis with UV radiation or anti-Fas antibody. Caspase-3 or
caspase-8 activity was measured in cell lysates made 4 h. Shown is
mean ± SEM of two to five independent experiments. In some
instances, error bars are too small to be seen.  , uninduced
mock-infected cells.
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Because viruses with deletion of the Us3 gene still retained some
antiapoptotic ability, we sought other HSV genes which might
mediate
the antiapoptotic effect. Our previous results of assays
using
inhibitors of late gene expression suggested that the antiapoptotic
effect was most likely encoded by an immediate-early or early
gene
(
16), so we initially focused our attention on one of the
immediate-early genes of HSV, Us12. Us12 has been shown to function
in
immune evasion by inhibiting CTL recognition of infected cells
through
prevention of peptide loading of major histocompatibility
complex class
I (
8,
14). Since another mechanism by which
HSV can evade
CTL is through inhibition of apoptosis (
16), we
tested
whether Us12 might also have an antiapoptosis function.
A mutant strain
of HSV,
d102, which is deleted for Us12, still
showed strong
inhibitory ability for both anti-Fas and UV-induced
apoptosis (Fig.
5C
and D), suggesting that this gene is not involved
in the suppression of
apoptosis. Similarly, another mutant HSV-1,
d90, which has
mutations of both Us12 and an adjacent gene, Us11,
showed strong
antiapoptotic ability (Fig.
5C and D). These results
demonstrate that
neither Us11 nor Us12 is required for the antiapoptotic
activity of
HSV.
Since HSV-1 deleted for Us3 still showed partial inhibition against
Fas-induced apoptosis, we postulated that the other antiapoptotic
function might be mediated through a protein targeted to the membrane,
where Fas and its associated molecules are found. HSV has several
glycoproteins which are transported to cytoplasmic membranes of
the
cell and are later incorporated into the viral envelope during
envelopment (
28). These glycoproteins have a variety of
functions
(
28) and are commonly involved in viral entry or
spread. However,
one small HSV gene, Us5, encodes a glycoprotein (gJ)
with no known
function (
11). HSV strains deleted for Us5
have been reported
to be phenotypically normal, including normal plaque
formation
and cell-to-cell spread of the virus (
4,
7). Since
these
properties do not exclude a role in modulation of apoptosis, we
tested whether this gene might be involved in HSV inhibition of
apoptosis. In contrast to the lack of effect on antiapoptotic
function
by deletions of Us11 and Us12, deletion of the HSV Us5
gene profoundly
affected the antiapoptotic ability of the virus.
The Us5 deletion
virus, RAS116, was completely unable to inhibit
Fas-mediated apoptosis
(Fig.
5E) and had also lost much of its
ability to inhibit UV-induced
apoptosis (Fig.
5F). Rescue of the
Us5 gene (virus RAS137) restored the
ability of the virus to fully
inhibit anti-Fas- or UV-induced
apoptosis. The role of Us5 in
the inhibition of DNA fragmentation
during apoptosis was confirmed
by agarose gel electrophoresis (not
shown). Cells infected with
RAS116 showed DNA fragmentation after UV or
anti-Fas treatment
very similar to that of uninfected cells. In
contrast, cells infected
with RAS137 showed no detectable DNA
fragmentation. These results
suggest that the Us5 gene product, like
Us3, acts to block portions
of the apoptosis pathway involved in both
anti-Fas- and UV-induced
apoptosis. However, the absolute requirement
for Us5 is for the
inhibition of Fas-mediated apoptosis, while partial
inhibition
of UV-induced apoptosis is possible without this
gene.
To investigate the effect of the Us5 gene on the apoptosis pathways
involved in Fas- or UV-induced apoptosis, we evaluated
caspase-3 and
caspase-8 activation in cells infected with the
Us5 deletion or rescue
virus. As expected, deletion of Us5 (RAS116)
almost completely
abrogated the ability of the virus to inhibit
caspase-3 or caspase-8
activation after Fas ligation (Fig.
5I
and J). Rescue of the Us5 gene
(RAS137) restored the ability of
the virus to inhibit activation of
these caspases. As also predicted
by the morphology experiments,
deletion of Us5 significantly reduced
the ability of the virus to
inhibit caspase-3 or caspase-8 activation
after UV irradiation (Fig.
5G
and H), although to a lesser extent
than after anti-Fas treatment.
Rescue of the Us5 gene restored
the ability of the virus to inhibit
activation of both caspases
after UV
irradiation.
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DISCUSSION |
These experiments provide several novel insights into the ability
of HSV-1 and HSV-2 to inhibit apoptosis of infected cells. First, we
have shown for the first time that the HSV-1 gene Us5 is required for
protection from apoptosis induced by certain stimuli. Second, our
results demonstrate that HSV infection of cells has significant
consequences on regulatory aspects of the apoptosis machinery, such as
caspase activation. Third, we have shown that the previously reported
(16) significant differences between HSV-1 and HSV-2 in the
ability to inhibit CTL-induced apoptosis extend to apoptosis induced by
UV irradiation or Fas ligation. Finally, our results are consistent
with the hypothesis that inhibition of apoptosis is an adaptive
strategy of HSV which might serve to augment viral yields in the
presence of proapoptotic stimuli.
Previous studies suggested that the antiapoptotic effect of HSV-1 was
mediated by an immediate-early or early gene. This conclusion was based
either on time course studies of the expression of the antiapoptotic
effect (16, 18) or on pharmacologic inhibition of HSV late
gene expression (16). Our studies are consistent with a
previous report by Leopardi et al. demonstrating that the Us3 gene of
HSV-1 was necessary to prevent apoptosis induced by the virus
(19). Our results extend these findings and establish that
Us3 also contributes to protection of infected cells from UV- or
anti-Fas-mediated apoptosis. However, our finding that partial
inhibition can occur in the absence of Us3 also suggests that other
potentially complementary mechanisms are operative.
Several authors have suggested that the antiapoptotic function of HSV
may be encoded by more than one gene. Nevertheless, we were somewhat
surprised to find that the HSV-1 gene Us5 contributed to the inhibition
of Fas- and UV-induced apoptosis. The Us5 gene contains a small open
reading frame predicted to encode a small, membrane-associated
glycoprotein, gJ (23). Recent work by Ghiasi et al. has
confirmed the expression and localization of gJ to the surface of
infected cells (11). Nevertheless, no function for this
protein has been found, and viruses deleted for Us5 have been reported
to be phenotypically normal, including normal plaque formation and
cell-to-cell spread of the virus (4, 7). We have been unable
to detect homology between Us5 and other known viral or cellular
antiapoptosis genes. Since Us5 is predicted to localize to the cell
membrane and appears especially important for the inhibition of
fas-mediated apoptosis, it may act directly upon signaling via the Fas
receptor. For example, Us5 might interfere with trimerization of Fas
after ligation (2), or it may interfere with recruitment of
Fas-associated molecules to the death-inducing signaling complex
(24, 25, 29). However, Us5 does not appear to contain a
death domain as do the viral FLICE-inhibitory proteins (v-FLIPs)
(6, 33), and so its mechanism of action is likely different
from that of the v-FLIPs. Inhibitors of death receptors can be bypassed
by many proapoptotic stimuli, including perforin/granzyme B
(17), which might explain the coevolution of other
antiapoptosis functions such as that encoded by Us3. Experiments are
under way to determine the exact mechanism of Us5 function.
Since Us5 appears to be more critical for the inhibition of
Fas-mediated apoptosis than is Us3, these genes may function in somewhat complementary roles. There may also be additional
antiapoptotic genes within the HSV genome. For example, a recent report
suggests that ICP27 may also contribute to inhibition of apoptosis by
HSV-1 (3). Experiments evaluating the role of other
immediate-early and early genes in the inhibition of apoptosis by HSV
are under way. It is possible that certain HSV genes are antiapoptotic
only in certain experimental systems, since some aspects of the
antiapoptotic effect appear to be cell type specific (10).
HSV late genes may also be involved in inhibition of apoptosis, and
transactivation of these genes is a possible mechanism of action for
immediate-early or early genes with regulatory functions.
We have previously reported that HSV-1, but not HSV-2, can protect
infected cells from apoptosis induced by ethanol or CTL (16). Our results here demonstrate that HSV-2 does not
inhibit Fas-mediated apoptosis but that the laboratory strain 333 may have a modest inhibitory effect on UV-induced apoptosis. This is in
contrast to clinical isolates of HSV-2, which fail to inhibit apoptosis
induced by either stimulus. It is possible that the inhibition of
apoptosis by 333 relates to its adaptation to laboratory growth. We are
presently testing additional clinical isolates to determine whether any
show antiapoptotic function. Since HSV-2 strain 333 inhibits caspase-3
and caspase-8 activation more strongly than it inhibits the morphologic
changes of apoptosis, the apoptosis-regulatory pathways may potentially
bypass the block of these caspases by HSV-2 and induce the terminal
changes of apoptosis through other mechanisms. Our finding that two HSV
genes, Us3 and Us5, have different and somewhat complementary
antiapoptosis functions may shed some light on the different inhibitory
abilities of HSV-1 and HSV-2. The Us3 gene product is well conserved
between HSV-1 and HSV-2, with 75% identity. In contrast, the Us5 gene
is less conserved between HSV-1 and HSV-2, with only 43% identity.
Deletion of either Us3 or Us5 from HSV-1 markedly degraded the ability of the virus to inhibit Fas- or UV-induced apoptosis, and so the sequence differences of HSV-2 relative to HSV-1 may be sufficient to
eliminate the antiapoptosis effect. The modest inhibitory effect of
HSV-2 strain 333 against UV-induced apoptosis may reflect the closer
conservation of the Us3 sequence, which appears to be more critical
than Us5 for this function. It is also possible, and perhaps likely,
that additional antiapoptosis genes exist in HSV-1 or HSV-2 and may
help to explain the differences seen between these viruses. Further
work defining the sequences responsible for these effects is in
progress and may help resolve these issues.
In addition to the role of Us3 and Us5 in the inhibition of Fas- or
UV-induced apoptosis demonstrated here, Leopardi et al. have previously
shown that Us3 acts to prevent apoptosis from being induced by the
virus (19). Apoptosis induced by HSV is not mediated though
the Fas receptor (15), and so these results taken together
argue that HSV-1 has an antiapoptosis function which acts at a more
central aspect of the apoptosis-regulatory pathway than specific Fas
receptor inhibitors such as the v-FLIPs (6, 33). Recent data
suggesting an inhibitory activity of HSV-1 which acts downstream of
caspase-3 (9) support this hypothesis. The ability of HSV-1
to inhibit both caspase-8 and caspase-3 activation after UV- or
anti-Fas antibody would be compatible with a second function acting
upon Fas or its accessory molecules, also known as the death-inducing
signaling complex (24, 25, 29). There is significant
feedback between caspases, and caspase-8 can be activated by UV
irradiation as well as Fas-Fas ligand interaction (27). In
our experiments, HSV-1 appears to inhibit caspase-8 activation even
more effectively after UV irradiation than after Fas ligation. If
caspase-8 activation during apoptosis induced by mechanisms such as UV
acts as an amplification mechanism for activation of other caspases,
use of such a strategy may explain the cooperative inhibitory functions
of Us3 and Us5 and the partial loss of inhibitory activity toward
UV-induced apoptosis seen with viruses deleted for Us5.
One of the purposes of this study was to determine whether some of the
differences in antiapoptotic ability between HSV-1 and HSV-2 seen in
our previous work might be due to the use of high-passage laboratory
strains of virus. The results presented here demonstrate that the
differences in inhibitory ability seen between HSV-1 and HSV-2 hold for
clinical isolates as well as laboratory strains. Nevertheless, there
are intrastrain differences in antiapoptosis potency. For example, the
HSV-2 laboratory strain 333 modestly inhibited UV-induced apoptosis
whereas the clinical isolates did not (Fig. 1 and 4). Ongoing
sequencing studies suggest that variations in the antiapoptosis genes
may be responsible for these differences. In addition, differences in
the temporal expression of antiapoptotic genes may explain some of
these differences.
Finally, it has been suggested that inhibition of apoptosis by HSV is a
helpful adaptation to the virus, resulting in increased viral yield in
the presence of proapoptotic stimuli such as cellular responses to
infection or immune pressure. The protection from apoptosis even at
time points near the completion of the viral life cycle (when
cytopathic effect becomes apparent) would support this suggestion.
Koyama and Miwa showed that induction of apoptosis with sorbitol in
infected HEp-2 cells modestly retarded virus multiplication
(18). However, the virus used in those experiments strongly
inhibited apoptosis, and thus the importance of inhibition of apoptosis
in the maintenance of viral yield could not be evaluated. The inability
of HSV-2 to inhibit UV-induced apoptosis compared to HSV-1, and the
development of HSV-1 strains with deletions of the antiapoptosis genes,
should provide the opportunity to directly test the importance of
inhibition of apoptosis in the presence of external proapoptotic
stimuli. We attempted to address this question in the Jurkat apoptosis
system, through a one-step growth curve in the presence or absence of
proapoptotic stimuli. Jurkat cells are clearly infectable by HSV, as
demonstrated by protection from apoptosis, and obvious cytopathic
effect at 24 h. However, there was no evidence of a viral eclipse
in the Jurkat system (Fig. 6), and viral
concentration never exceeded the levels of input virus (5 PFU/cell). On
the contrary, viral titers slowly decayed over time, suggesting that
viral replication in Jurkat cells is a relatively inefficient process.
Treatment of cultures at 2 or 5 h postinfection with UV caused a
rapid 2-log decrease in viral titer, possibly due to inactivation of
unabsorbed, cell-free virus. The lack of efficient replication of HSV
in Jurkat cells was evident in unirradiated cells as well, and viral
titers slowly decayed in these cells over time. Thus, the poor
replication of HSV in Jurkat cells precludes conclusions regarding the
effect of inhibition of apoptosis on viral replication. We are
currently pursuing similar time course experiments using cells better
suited for replication of virus, such as the HEp-2 cells used by Koyama and Miwa (18), and also primary keratinocytes. These studies should allow determination of whether the inhibition of apoptosis has a
positive effect on viral replication. Additional studies using single
and multiple gene deletions will be required to evaluate the roles of
Us3 and Us5 in the maintenance of viral yield in the presence of
proapoptotic insults to the infected cell. Such studies may reveal an
intricate system of redundant or complementary genes in HSV-1. Similar
studies using more physiologic proapoptotic stimuli may also establish
whether inhibition of apoptosis is an adaptive strategy that can be
used by HSV-2 as well.
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|
FIG. 6.
One-step growth curve of HSV in Jurkat cells. Jurkat
cells were infected with HSV-1 (F28700) or HSV-2 (F43031) at 5 PFU/cell. Infected cultures were either left unirradiated or
UV-irradiated at 2 or 5 h postinfection. Viral titers at the
indicated time points were determined by a standard plaque assay.
|
|
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grants K08-AI-01504 to K.R.J. and
R01-AI-30731 to L.C.
We thank David Koelle, Jonathan Tait, and Nelson Fausto for useful discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Room D3-100,
Fred Hutchinson Cancer Research Center, 1100 Fairview Ave. North,
Seattle, WA 98109. Phone: (206) 667-6793. Fax: (206) 667-4411. E-mail: kjerome{at}u.washington.edu.
| |
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Abstract
Introduction
