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Previous Article | Next Article 
Journal of Virology, April 2000, p. 3650-3658, Vol. 74, No. 8
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Bystander Sensitization to Activation-Induced Cell
Death as a Mechanism of Virus-Induced Immune Suppression
Christopher C.
Zarozinski,
James M.
McNally,
Barbara L.
Lohman,
Keith A.
Daniels, and
Raymond M.
Welsh*
Department of Pathology, University of
Massachusetts Medical Center, Worcester, Massachusetts 01655
Received 18 October 1999/Accepted 18 January 2000
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ABSTRACT |
Viral infections which induce strong T-cell responses are often
characterized by a period of transient immunodeficiency associated with
the failure of host T cells to proliferate in response to mitogens or
to mount memory recall responses to other antigens. During acute
infections, most of the activated, proliferating virus-specific T cells
are sensitized to undergo apoptosis on strong T-cell receptor (TCR)
stimulation, but it has not been known why memory T cells not specific
for the virus fail to proliferate on exposure to their cognate antigen.
Using a lymphocytic choriomeningitis virus (LCMV) infection model in
which LCMV-immune Thy 1.1+ splenocytes are adoptively
transferred into Thy 1.2+ LCMV carrier mice, we demonstrate
here that T cells clearly defined as not specific for the virus are
sensitized to undergo activation-induced cell death on TCR stimulation
in vitro. This bystander sensitization was in part dependent on the
expression of Fas ligand (FasL) on the activated virus-specific cells
and gamma interferon (IFN-
) receptor expression on the bystander T
cells. We propose that FasL from highly activated antiviral T cells may
sensitize IFN--conditioned T cells not specific for the virus to
undergo apoptosis rather than to proliferate on encountering antigen.
This may in part explain the failure of memory T cells to respond to
recall antigens during acute and persistent viral infections.
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INTRODUCTION |
In 1908 von Pirquet reported that
individuals acutely infected with measles virus failed to mount a
delayed-type hypersensitivity reaction to tuberculin even though they
had been previously immunized (35). After resolution of the
infection, responsiveness to this memory recall antigen returned.
Similar types of transient immune deficiencies have subsequently been
reported during many viral infections, including those caused by
Epstein-Barr virus, cytomegalovirus, and human immunodeficiency virus
(HIV) in humans and by lymphocytic choriomeningitis virus (LCMV) in the
mouse model (7, 21, 25, 27). In addition to the failure to
respond to memory recall antigens, T cells from infected individuals
fail to proliferate in response to signals delivered via the T-cell
receptor (TCR) by mitogenic lectins, superantigens, or anti-CD3
antibody. In several infections, this transient immune deficiency has
been correlated with the induction of apoptosis in the highly activated T cells, which express CD95 (Fas) and CD95 ligand (FasL) (1, 7,
21, 25).
Apoptosis by activation-induced cell death (AICD) is now a
well-characterized feature of activated T-cell populations that become
strongly signaled through their TCR. The interaction of Fas with FasL
after TCR stimulation causes Fas to associate with the intracytoplasmic
Fas-activated death domain, which initiates the apoptotic pathway
(16). Recent work has shown that most of the T cells
proliferating in response to viral infections are highly activated
virus-specific cells, which would be expected to eventually undergo
AICD on appropriate signalling (9, 23). This would explain
the failure of the virus-induced T-cell population to respond to
nonspecific T-cell mitogens, but this observation does not explain why
memory T cells should have deficient responses to their specific
cognate antigens. These deficient memory responses might be a
consequence of a dilution of memory cells by the proliferating virus-specific cells, of a redistribution of memory T cells such that
they are no longer present in the peripheral blood or spleen populations used for testing their function, or of the action of
immunosuppressive factors which inhibit their ability to function. Alternatively, as shown here, these non-virus-specific T cells may
become sensitized in a bystander fashion to undergo AICD on receptor stimulation.
The distinctions between virus-specific and nonvirus-specific T cells
can be blurred because many memory T cells can be stimulated during
viral infections by cross-reactive interactions (29). We
have therefore developed models to clearly identify, in the same
systems, T cells that are specific and those that are not specific for
viral antigens (38). In this way, one can ask whether bystander events occurring as a consequence of the T-cell response to
viral infections alter the activity of T cells whose receptors are not
being triggered by the virus. We have used the highly defined LCMV
infection of the mouse to explore these processes. The acute LCMV
infection is associated with a marked expansion of the CD8 T-cell
population, and most of the activated T cells during the LCMV infection
are virus specific (23, 25, 29, 38). Between 6 and 12 days
postinfection, the host undergoes a transient but severe state of
immune deficiency characterized by impaired proliferative response in
vitro and by the induction of apoptosis in those T cells
(25). This immune deficiency, however, is not found in mice
harboring persistent LCMV infection as a consequence of congenital
infection. Those persistently infected "LCMV carrier" mice clonally
delete their LCMV-specific T cells but can make normal T-cell responses
to other antigens (11, 14). If T cells from Thy
1.1+ LCMV-immune mice are transferred into the tolerant Thy
1.2+ carrier mice, they proliferate in response to the
viral antigens present, but the host cells, which cannot respond to
LCMV antigens, do not increase in number (11, 12, 38). This
model can therefore be used to ask how a vigorous antiviral T-cell
response can affect the biology of T cells defined as being virus
nonspecific but nevertheless coexisting in this milieu.
Here we show that a potent antiviral T-cell response causes T cells not
participating in the immune response to undergo AICD rather than to
proliferate on TCR stimulation. This bystander sensitization to AICD
may explain the immunosuppression that follows infections with many viruses.
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MATERIALS AND METHODS |
Mice.
Conventionally housed male and female C57BL/6,
B6Smn.C3H-Faslgld,
B6.MLR-Faslpr, and B6.PLThy1a/C mice
were purchased from the Jackson Laboratory (Bar Harbor, ME). C57BL/6
HY-transgenic mice, whose transgenic TCR recognizes the male-specific
antigen HY in the context of H2-Db, were a gift
from B. J. Fowlkes (National Institutes of Health, Bethesda, Md.)
(26). 129 SV/EV mice, homozygous for a targeted mutation
that disrupts the murine gamma interferon (IFN-) gene, were a gift
from M. Aguet (University of Zurich, Zurich, Switzerland) (22). HY transgenic and IFN- receptor knockout mice
strains were bred and maintained under microisolator conditions in the University of Massachusetts Medical School Department of Animal Medicine. Persistently infected LCMV carrier C57BL/6,
B6.MLR-Faslpr, and IFN- receptor knockout
mice were bred in the Biocontainment Suite at the University of
Massachusetts Medical School Department of Animal Medicine. All mice
examined were major histocompatibility complex compatible, and except
for the IFN- receptor knockout 129/SV mice, all were congenic
strains on the C57BL/6 background.
Virus.
The LCMV Armstrong strain was propagated in baby
hamster kidney (BHK21) cells. Unless otherwise noted, mice were
injected intraperitoneally i.p. with 4 × 104 PFU of virus.
Antibody and complement depletion.
Spleens were isolated and
ground between the frosted ends of two glass microscope slides. The
cell suspension was then passed through a fine nylon mesh to obtain a
single-cell suspension. Erythrocytes were lysed by briefly suspending
the spleen cell pellet in a 0.84% NH4Cl solution. To
enrich for T cells prior to in vitro culture, granulocytes and B cells
were eliminated by treatment with antibody J11d (2) and
complement. After counting, 5 × 107 spleen leukocytes
were treated with 50 µl of J11d (ammonium sulfate-precipitated ascites) for 45 min at 4°C and then washed twice with complete RPMI
1640. The cells were incubated at 37°C for 45 min in a humidified 5%
CO2 incubator with 2 ml of a 1:10 dilution of rabbit C'
(Pel-Freez Clinical Systems, Brown Deer, Wis.). They were washed twice
in complete RPMI 1640 and recounted. In vitro T-cell depletions were performed as above, except that 25 µl of either anti-Thy1.1 or anti-Thy1.2 antibody (Pharmingen, San Diego, Calif.) was used instead
of J11d.
Adoptive transfer of immune spleen cells to LCMV carrier
mice.
A total of 2 × 107 to 4 × 107 spleen leukocytes from LCMV-immune B6.PL
Thy1a/Cy mice (Thy 1.1+) were injected
intravenously via the retro-orbital sinus into C57BL/6 LCMV carrier
mice (Thy 1.2+). These unfractionated donor cell
populations consisted of about 10% CD8 T cells and 20% CD4 T cells.
At 6 days after adoptive transfer, spleen cell populations were
examined for reconstitution with donor Thy 1.1+ T cells. As
shown previously (38), few (<1%) donor T cells were
observed in spleen lymphocytes of recipient mice injected with
LCMV-naive donor T cells whereas about 5% (with some variation) of
lymphocytes were donor T cells in mice inoculated with LCMV-immune Thy
1.1+ cells. By day 6, the great majority (>70%) of donor
T cells in the recipients were CD8+ cells and more than
80% of the donor CD8 and CD4 T cells expressed high levels of the
activation/memory marker CD44. In the host Thy 1.2+ T-cell
populations from mice reconstituted with naive donor cells, about
one-third of the host CD8 T cells were defined as CD44+ and
the proportion of CD44+ host CD8 T cells declined slightly
after the adoptive transfer (38). Similar trends were seen
with the CD4 T-cell population (data not shown). Spleens from recipient
mice were harvested at 6 days posttransfer, subjected to J11d antibody
and complement depletion, and then stimulated with plate-bound anti-CD3
(see above). Prior to culture, the T-cell-enriched populations
originating from Thy 1.2+ LCMV carrier mice reconstituted
with naive donor cells were 44 to 55% Thy 1.2+; cultures
originating from Thy 1.2+ LCMV carrier mice reconstituted
with Thy 1.1+ LCMV-immune donor cells ranged from 33 to
42% host Thy 1.2+ cells and 4 to 13% donor
Thy1.1+ cells.
Flow cytometry.
After being stained, cells were analyzed or
sorted by flow cytometry using a FACSTAR apparatus (Becton-Dickinson,
San Jose, Calif.). Data analysis was performed using the program Cell
Quest (Becton-Dickinson). Flow cytometry for the expression of Fas was done using phycoerythrin-conjugated hamster anti-mouse Fas
immunoglobulin G monoclonal antibody clone Jo2, purchased from Pharmingen.
Detection of transgenic T cells.
Spleen cells from
HY-TCR-transgenic mice were prepared as described above, and
106 cells were incubated with normal rat serum for 20 min
at 4°C. The cells were then incubated with the monoclonal antibody
T3.70 (a kind gift from Hung-sia Teh, University of British Columbia, Vancouver, Canada) for 30 min on ice (26). The cells were
then washed twice and blocked again with normal rat serum at 4°C for 20 min. They were stained with anti-CD8-phycoerythrin (Gibco/BRL, Grand
Island, N.Y.) and rabbit anti-mouse immunoglobulin G1-fluorescein isothiocyanate (Cappel, Aurora, Ohio) for 25 min at 4°C. They were
then washed twice and fixed with 2% paraformaldehyde.
TdT-mediated dUTP biotin nick end labeling (TUNEL) flow
cytometry.
Forty- eight-well plates (Costar) were coated overnight
at 4°C with a 1:25 dilution of anti-CD3 (Pharmingen). The next day, the plates were washed twice with phosphate-buffered saline (PBS), and
106 T-cell-enriched spleen cells were added to each well.
After 2 days of in vitro culture in the presence of plate-bound
anti-CD3, apoptotic cells were detected by flow cytometry using the
method of Ralph Budd (University of Vermont College of Medicine)
adapted from reference 34. Surface staining of
approximately 106 lymphocytes was performed as described
above, and the cells were then fixed with 1% paraformaldehyde for 15 min at 4°C. After being washed with PBS, the cells were permeabilized
by treatment with 70% ethanol for 15 min at 4°C. The permeabilized
cells were then washed twice with cold PBS and suspended for 1 h
at 37°C in reaction buffer containing 1× terminal
deoxyribonucleotidyltransferase (TdT) buffer, 2.5 mM cobalt chloride,
10 U of TdT, and 0.5 nmol of biotin-dUTP (Boehringer-Mannheim,
Indianapolis, Ind.). After being washed twice, the cells were stained
with streptavidin-TRICOLOR (Caltag, San Francisco, Calif.) for 22 min
at 4°C and fixed in 1% paraformaldehyde.
Proliferation assay.
After 2 days of in vitro culture with
plate-bound anti-CD3, 2 × 105 cells in 200 µl of
RPMI-MLC medium were placed in 96-well U-bottom microtiter plates
(Falcon). Each well was then pulsed with 50 µl of complete RPMI
medium containing 5 × 10
5 M 2-mercaptoethanol and 1 µCi of [3H]thymidine (Amersham) and incubated for
6 h at 37°C in a humidified 5% CO2 incubator. The
plates were then harvested onto fiberglass filter mats, and
[3H]thymidine incorporation was determined using a
Betaplate scintillation counter (Wallac, Gaithersburg, Md.).
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RESULTS |
Bystander sensitization of T cells to AICD during an
antiviral T-cell response.
Transfer of Thy 1.1+
T cells from LCMV-immune mice into Thy 1.2+
persistently infected LCMV carrier mice results in a
proliferation of donor cells and a partial and sometimes complete
clearance of infectious virus (11, 12, 38). We have shown
that the potent antiviral T-cell response mounted by the LCMV-specific memory T cells after transfer did not result in any detectable increase
in the number, size, or activation antigen status of the LCMV-tolerant
host CD8 T cells (38). Here we questioned whether, on TCR
stimulation, the proliferation of those host T cells was impaired and
whether they underwent AICD. Thus, after adoptive transfer of Thy
1.1+ LCMV-immune spleen cells into Thy 1.2+
LCMV carrier mice, splenocytes were harvested, enriched for T cells,
and cultured with plate-bound anti-CD3, and after 2 days TUNEL flow
cytometry was performed. As shown in Fig.
1, anti-CD3 treatment resulted in the
apoptosis of CD8+ T cells from mice 8 days after LCMV
infection, consistent with the earlier report that these highly
activated T cells are very susceptible to AICD (25). Here we
use the TUNEL stain exclusively as an indicator of apoptosis, but we
have documented apoptosis in anti-CD3-stimulated day 8 T-cell
populations previously by several other techniques, including DNA
ladder analysis and propidium iodide/light scatter/forward-scatter flow
cytometric analyses (24, 25). Conversely, CD8+
cells from LCMV carrier mice underwent very little apoptosis during the
2 days in culture with anti-CD3; T cells from uninfected control mice
behaved similarly to those from carrier mice (data not shown but
documented by us in reference 19). This result is
consistent with the fact that naive or resting T cells will proliferate
on TCR cross-linking. In LCMV carrier mice adoptively reconstituted
with LCMV-immune spleen cells, the activated donor CD8+ T
cells, much like T cells from acutely infected mice, underwent apoptotic cell death after exposure to anti-CD3. In contrast to the
CD8+ T cells taken from the unmanipulated LCMV carrier
mice, the CD8+ host T cells present in the adoptively
reconstituted mice also underwent apoptotic cell death after TCR
stimulation. This result, which was obtained in over 10 separate
experiments, strongly supports the hypothesis that CD8+ T
cells not specific for the virus are sensitized during a potent antiviral T-cell response to undergo AICD after TCR stimulation.
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FIG. 1.
CD8+ host cells in LCMV carrier C57BL/6 mice
become sensitized to undergo apoptosis after adoptive transfer of
LCMV-immune C57BL/6 mouse spleen cells. Splenocytes enriched for T
cells by treatment with J11d monoclonal antibody and complement were
cultured with plate-bound anti-CD3 for 48 h and tested for
apoptosis by the TUNEL assay. T-cell preparations were from untreated
LCMV carrier mice, which are similar to uninfected control mice, as
shown in reference 19 (A), or from normal mice 8 days after acute LCMV infection (B). In panels C and D, T-cell-enriched
splenocytes were taken from Thy 1.2+ LCMV-carrier mice 6 days after transfer of 4 × 107 LCMV-immune Thy
1.1+ spleen cells. By gating on host Thy 1.2+
(C) or donor Thy 1.1+ (D) cells, apoptosis in each
population was determined by TUNEL stain.
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To determine whether these host CD8+ T cells were capable
of proliferating in response to anti-CD3,
[3H]thymidine incorporation assays were performed.
The results of a representative experiment are shown in Table
1. Spleen cells from both C57BL/6 mice
and LCMV carrier mice proliferated well after culture with anti-CD3.
However, splenocytes taken from mice on day 8 after LCMV infection or
from LCMV carrier mice 6 days after adoptive transfer of LCMV-immune
spleen cells incorporated very little [3H]thymidine,
consistent with the fact that these cells were undergoing apoptosis
rather than proliferating. In 10 individual experiments, the reduction
in [3H]thymidine incorporation between LCMV carrier
mice (either unreconstituted or reconstituted with naive cells) and
immune-cell adoptively reconstituted LCMV carrier mice ranged from a
high of 242-fold to a low of 3-fold, with an average of 60-fold.
Because most of the T cells put into culture were of host origin, this
suggests that there was a marked inhibition of proliferation of the
host T cells.
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TABLE 1.
Inhibition of proliferation of T cells from LCMV carrier
mice adoptively reconstituted with LCMV-immune splenocytes
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To determine which cell populations in the transferred donor leukocyte
preparations were required to induce bystander sensitization to AICD,
LCMV carrier mice were reconstituted with LCMV-immune spleen cells,
either treated in vitro with antibody and complement to deplete Thy
1+ T cells or treated with complement alone. Spleen
cells from unmanipulated LCMV carrier mice survived (Fig.
2A) and proliferated (61,917 ± 14,639 cpm), whereas splenocytes taken from carrier mice
reconstituted with complement-treated LCMV-immune spleen cells
underwent significantly more apoptosis (Fig. 2B) and proliferated less
than did unmanipulated carriers (30,993 ± 2,379 cpm). In
contrast, spleen cells taken from mice reconstituted with spleen cells
treated with anti-Thy1.2 plus complement survived (Fig. 2C) and
incorporated nearly as much [3H]thymidine
(53,864 ± 8,939 cpm) as did the unmanipulated carriers. This
result suggests that the donor T cells are required to sensitize the
host T cells to AICD.
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FIG. 2.
Donor T cells are required to induce susceptibility to
AICD. TUNEL flow assays were performed on splenocytes from
unmanipulated Thy 1.2+ LCMV carrier C57BL/6 mice (A), LCMV
carrier C57BL/6 mice adoptively reconstituted with 2.5 × 107 complement-treated LCMV-immune Thy 1.2+
C57BL/6 mouse spleen cells (B), or LCMV carrier C57BL/6 mice adoptively
reconstituted with 2.5 × 107 LCMV-immune spleen cells
depleted of T cells by treatment with anti-Thy 1.2 antibody and
complement (C). Histograms represent the incorporation of the TdT label
on the gated T-cell populations.
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Naive splenocytes transferred into LCMV carrier mice do not
substantially expand in number or effect the clearance of virus (11, 12, 38). Splenocytes from LCMV carrier mice
reconstituted with 3 × 107 LCMV-naive spleen cells
proliferated to the same extent as did splenocytes from unmanipulated
LCMV carrier mice and displayed no evidence of sensitization to
AICD after anti-CD3 stimulation (data not shown). Thus, LCMV carrier
mice and LCMV carrier mice that received naive spleen cells were used
interchangeably as controls. It should also be noted that after the 2 days in culture with anti-CD3, the level of CD8 expression was
often dim, making it sometimes difficult to determine which cells were
CD8dim versus CD8. As a result, host and
donor cell populations were distinguished based on expression of the
strongly staining Thy 1 allotypic markers in most of the following experiments.
Exogenous accessory cells cannot rescue host T cells from
AICD.
The proliferation of T cells in vitro often requires the
presence of accessory cells such as antigen-presenting cells (APCs) in
the culture (9). It has also been suggested that the
inability of T cells to proliferate during acute viral infections may
be the result of an APC defect (5, 6, 10, 27). To determine if bystander sensitization to AICD was the result of the absence of
some vital APC-derived positive signal that was required for the
proliferation of host T cells in vitro, exogenous APCs were added to
culture wells containing splenocytes taken from the adoptively reconstituted LCMV carrier mice. These exogenous APCs were T-depleted spleen cells from uninfected C57BL/6 mice. T cells from unmanipulated LCMV carrier mice proliferated vigorously (174,583 ± 36,381 cpm) and did not undergo apoptosis (Fig. 3A),
whereas spleen cells taken from LCMV carrier mice previously
reconstituted with Thy 1.1+ LCMV-immune splenocytes
underwent apoptosis (Fig. 3B) and proliferated very poorly (2,224 ± 91 cpm). The addition of T-depleted normal spleen cells as accessory
cells failed to rescue the host T cells from apoptotic death
(Fig. 3C) or to substantially increase their [H3]thymidine incorporation (4,490 ± 261 cpm). This result was seen in two other experiments and demonstrates
that the lack of a vital APC-derived signal could not explain the
observed immune suppression after in vitro stimulation with anti-CD3.
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FIG. 3.
Exogenous APCs do not rescue host T cells from AICD.
TUNEL flow assays were performed on splenocytes from unmanipulated LCMV
carrier C57BL/6 mice (A), LCMV carrier C57BL/6 mice adoptively
reconstituted with 3 × 107 LCMV-immune spleen cells
(B), or LCMV carrier C57BL/6 mice adoptively reconstituted with 3 × 107 LCMV-immune Thy 1.1+ spleen cells and
then cultured 1:1 in the presence of T-cell-depleted spleen cells from
uninfected C57BL/6 mice (C). Histograms represent the incorporation of
the TdT label in the host Thy 1.2+ cells.
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Activated accessory cells do not suppress proliferative T-cell
responses under the test conditions.
It has been reported that in
some systems, adherent accessory cells from virus-infected hosts may
inhibit the proliferation of T cells (13), and while we have
found similar types of inhibition under certain high-cell-density
culture conditions, significant levels of inhibition did not
occur under the culture conditions of this study. Table
2 shows that mixtures of unfractionated or T-cell-depleted spleen leukocytes from adoptively
reconstituted LCMV carrier mice with control leukocytes or with
leukocytes from unreconstituted LCMV carrier mice caused very low or
modest levels of inhibition of proliferation, other than that accounted
for by the 1:2 dilution occurring as a consequence of the mixture. This
is consistent with two earlier reports which showed that day 8 splenocytes from acutely LCMV-infected mice did not inhibit the
proliferation of day 0 splenocytes (25, 28). These
experiments and those in the section above argue that the bystander
sensitization to apoptosis and proliferative inhibition is not, under
the conditions of these assays, a function of non-T accessory cells and
argue that a sensitization to apoptosis may be occurring in vivo before the cells are put in culture.
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TABLE 2.
Proliferation of T cells after coculture with splenocytes
from adoptively reconstituted LCMV carrier mice
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Roles of donor and host T cells in the proliferative
responses.
The experiments described above showed that depletion
of donor T cells in the LCMV-immune splenocyte populations before
adoptive transfers into carrier mice eliminated the ability of donor
cell populations to sensitize host T cells to proliferative inhibition and to apoptosis. Experiments were done to test if donor T cells were
required within the in vitro proliferative assay that occurred after
the adoptive reconstitution. Donor T cells were depleted from the
reconstituted T-cell population by staining them with anti-Thy 1.1 and
sorting them away from the remaining cells. Spleen cells from
unmanipulated LCMV-carrier mice proliferated strongly after anti-CD3
treatment (116,029 ± 3,387 cpm), whereas splenocytes from
reconstituted LCMV carrier mice proliferated poorly
(28,762 ± 2,515). Removal of the Thy 1.1+ donor cells
from the population increased the proliferation only slightly
(41,170 ± 7,485). Flow TUNEL data for apoptotic cells in this
experiment showed 33% apoptotic cells in the cultures of the
unreconstituted mice but over 50% apoptotic cells in the reconstituted cell cultures, with or without Thy 1.1 cell
depletion (results not shown). Similar patterns of proliferation
and TUNEL results were also noted in reconstituted mice whose
cells were treated with anti-Thy1.1 antibody and complement to deplete
donor cells, but data are presented only for the sorted cells, whose depletions were the most quantitative. These experiments indicate that
even though donor T cells were required in vivo to bring about this
sensitized state, the continued presence of highly activated donor T
cells in the cultures was not required for sensitivity of the host
cells to proliferative inhibition and to apoptosis ex vivo.
Experiments were also performed to determine if host Thy
1.2+ cells purified by cell sorting were refractory to
proliferation in response to anti-CD3. Table
3 lists five experiments showing that
highly purified (>92% pure) host Thy 1.2+ cells from
unreconstituted or naive cell-reconstituted carrier mice proliferated
substantially better than did Thy 1.2+ host cells purified
from carrier mice reconstituted with LCMV-immune splenocytes. This
inhibition in proliferation of purified host cells was not as great
that seen in the presence of donor T and activated accessory cells
(Table 1), but the proliferative response of the purified host T cells
was clearly weakened by their previous in vivo exposure to a T-cell
response to a viral infection.
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TABLE 3.
Impaired proliferation of purified bystander LCMV carrier
host T cells from Thy 1.2+ LCMV carrier mice adoptively
reconstituted with LCMV-immune Thy
1.1+ splenocytesa
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Role of IFN- in bystander sensitization to AICD.
We have
recently reported that T cells derived from mice genetically deficient
in the IFN- receptor are relatively resistant to AICD after acute
LCMV infection (19). To ascertain what role, if any, IFN-
played in bystander sensitization of host T cells to AICD, LCMV-immune
Thy 1.1+ spleen cells were adoptively transferred into Thy
1.2+ LCMV carrier mice lacking the IFN- receptor. Under
these conditions, the host T cells would be unable to respond to the
IFN- that was produced by the activated proliferating donor cells.
The results of these adoptive-transfer experiments are shown in Fig.
4 and Table
4. T cells from persistently infected
IFN- receptor knockout mice and T cells from IFN- receptor
knockout mice reconstituted with LCMV-naive splenocytes were relatively
resistant to AICD (Fig. 4A and B). In IFN- receptor knockout mice
adoptively reconstituted with LCMV-immune Thy 1.1+ spleen
cells (Fig. 4C), the extent of apoptosis was slightly greater than that
seen in IFN- receptor knockout carrier mice reconstituted with
LCMV-naive spleen cells (42 and 32%, respectively) but not nearly as
extensive as that seen in immune cell-reconstituted persistently
infected normal mice capable of responding to IFN- (42 and 71%,
respectively [Fig. 4D]). The [3H]thymidine
incorporations from three separate reconstitution experiments involving
persistently infected IFN- receptor knock-out mice are shown in
Table 4. In agreement with the TUNEL data, the inhibition of
proliferation after reconstitution was not as profound when the host T
cells cannot respond to IFN-. This result suggests that IFN- may
play a role in sensitizing host cells to undergo apoptosis after TCR
ligation. Some sensitization, however, clearly can take place in the
absence of IFN-.
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FIG. 4.
Bystander sensitization to apoptosis is inhibited in
IFN- receptor knockout mice. TUNEL flow assays were performed on
splenocytes from unmanipulated IFN- receptor knockout LCMV carrier
129/SV mice (A), IFN- receptor knockout 129/SV LCMV carrier mice
reconstituted with 3 × 107 LCMV-naive C57BL/6 mouse
spleen cells (B), IFN- receptor knockout LCMV carrier 129/SV carrier
mice reconstituted with 3 × 107 LCMV-immune Thy
1.1+ C57BL/6 spleen cells (C), or wild-type LCMV carrier
C57BL/6 mice reconstituted with 3 × 107 LCMV-immune
C57BL/6 mouse spleen cells (D). LCMV carrier normal 129/SV mice were
not available for this experiment, but we have shown previously that T
cells from these mice become highly sensitized to apoptosis during the
acute LCMV infection (19). Histograms represent the
incorporation of the TdT label in the host Thy 1.2+ T
cells.
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Role of FasL in bystander sensitization to apoptosis.
Fas and
FasL play key roles in regulating T-cell apoptosis. To see what, if
any, role this receptor-ligand pair plays in inducing bystander AICD,
the gld mouse, which harbors a point mutation (Phe to Leu)
in the carboxy terminus of the FasL molecule (20, 31),
ablating its ability to induce apoptosis in Fas-expressing cells, was
used as a source of LCMV-immune T cells. In these experiments Thy
1.2+ LCMV carrier mice were adoptively reconstituted with
splenocytes from Thy 1.2+ LCMV-immune gld mice
(Table 5; experiments 1 to 3); we have shown that gld mice have normal numbers of memory cytotoxic
T lymphocytes as detected by the limiting-dilution assay
(19). Reconstitution of these cells in this Thy
1.2-syngeneic system was demonstrated by an increase in the percentage
of CD8 splenocytes expressing activation markers (large
CD44high CD62Llow-expressing cells) 6 days
postinfection. To further confirm that adoptively transferred T cells
from gld mice can otherwise function properly in vivo,
3 × 107 splenocytes from naive or LCMV-immune C57BL/6
mice or gld mice were transferred intravenously into
6-week-old C57BL/6 mice infected 1 day previously with 5 × 104 PFU of LCMV intraperitoneally. The next day, spleens
were harvested and the titer of LCMV plaques was determined; a
reduction in PFU has been shown in this system to be a function of
MHC-restricted CD8 T cells (39). Splenocytes from
LCMV-immune C57BL/6 and gld mice each led to similar
1-log-unit reductions in viral titers (log10 PFU/spleen
after reconstitution with splenocytes from naive C57BL/6, 4.4 ± 0.1; immune C57BL/6, 3.2 ± 0.1; naive gld, 4.2 ± 0.4; immune gld, 3.3 ± 0.0), arguing that transferred
gld-immune T cells functioned properly in vivo to clear the
virus. However, when LCMV carrier mice were reconstituted with spleen
cells from LCMV-immune gld mice, the inhibition in
[H3]thymidine incorporation was significantly lower
than that seen when FasL+/+ LCMV-immune spleen cells were
used for reconstitution. In Table 5 experiment 1, there appeared to be
some effect of the immune gld cells, but it was much smaller
than that seen with normal immune cells in the experiment in Table 1
and in experiments 2 to 4 in Table 5. In one experiment, Thy
1.1+ LCMV carrier mice, which were of very limited
availability, were reconstituted with cells from LCMV-immune Thy
1.2+ gld mice (Table 5, experiment 4) and the
proliferation was substantially lower in mice reconstituted with
LCMV-immune normal C57BL/6 mouse control cells than with LCMV-immune
gld cells. Figure 5 shows the
results of one of three similar TUNEL experiments, indicating that T
cells in adoptively reconstituted carrier mice were not substantially sensitized to undergo apoptosis if reconstituted with
LCMV-immune gld mouse splenocytes. These data suggest that expression of FasL on the activated donor cells is important for the sensitization of host T cells for antiproliferative and apoptotic effects.
View this table:
[in this window]
[in a new window]
|
TABLE 5.
T-cell proliferation after adoptive reconstitution of
LCMV carrier mice with spleen cells from LCMV-immune or naive
gld mice
|
|
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 5.
Immune splenocytes from C57BL/6 congenic gld
mice are inefficient at sensitizing cells from adoptively reconstituted
LCMV carrier mice to apoptosis on anti-CD3 stimulation. LCMV carrier
C57BL/6 Thy 1.2+ mice were either unreconstituted (A) or
reconstituted with splenocytes from LCMV-immune control C57BL/6 (B) or
LCMV-immune gld (C) Thy1.2+ mice, in a method
similar to that used in Fig. 1. This figure shows the results for the
total T-cell populations from these mice, since both host and donor
cells were Thy 1.2+.
|
|
Similar types of experiments were done using LCMV carrier
lpr mice, which have a mutation in Fas (36, 37),
as recipients for normal LCMV-immune T cells. There was no induced
inhibition of host T-cell proliferative responses (data not shown), but
these experiments were uninterpretable because T cells from
lpr mice are in general resistant to AICD (19)
and because fluorescence analyses indicated that Thy 1.1+
donor cells did not reconstitute in the Thy 1.2+
lpr mice; this may be due to the reported elevations in the
levels of lpr mouse FasL (37), which may
interfere with the expansion of activated T cells in a manner similar
to the phenomenon that we are describing here.
Inhibition of proliferation in LCMV-infected HY transgenic
mice.
To examine the effects of a more typical acute viral
infection on T cells known not to be specific for the virus,
HY-specific transgenic T-cell C57BL/6 mice were used. These mice have a
"leaky" transgenic T-cell repertoire in that they contain a
considerable array of T cells that do not express both the 
and 
chains of the HY-specific TCR; about 30% of the CD8 T cells express
both receptors and have HY specificity. We have shown that LCMV induces in these mice a strong T-cell response that does not elicit the proliferation of the transgenic T cells, which are detectable by the
monoclonal antibody T3.70 (38). By 8 days postinfection, 15 to 25% of the CD8 T cells express the HY-specific transgene (37), yet [3H]thymidine incorporation
assays showed that these total T-cell populations proliferated
extremely poorly in response to anti-CD3. Splenocytes from uninfected
HY transgenic mice proliferated well after culture with anti-CD3 (cpm
ranging in three experiments from 111,218 ± 21,424 to
257,934 ± 363). In contrast, splenocytes from HY transgenic mice
8 days after LCMV infection proliferated very poorly, from a low of
424 ± 23 cpm up to a maximum of only 5,463 ± 77 cpm after
culture with anti-CD3. Predictively, TUNEL stains showed high levels of
cell death in these cultures; however, HY+ cells could not
be distinguished from the rest of the T cells because they could not be
detected after anti-CD3 stimulation, either because of cell loss by
apoptosis or because of receptor downregulation. Nevertheless, the
extremely impaired uptake of the radiolabel, the low recovery of cells
after stimulation, and the high frequency of TUNEL staining in the
remaining cells indicates that the "bystander" HY+
cells died in these cultures.
| |
DISCUSSION |
Here we show that T cells clearly defined as being not virus
specific fail, during a potent antiviral immune response, to proliferate on TCR ligation but instead undergo apoptosis. This bystander sensitization to AICD occurred as a consequence of an ongoing
virus-specific T-cell response and appeared to be dependent on the
expression of FasL on the activated proliferating cells, since
sensitization did not occur when the virus-specific T cells lacked
expression of FasL. This might indicate that FasL on the virus-specific
cells interacts with Fas on the bystander cells before, during, or
after receptor engagement and directs them into a death pathway. The
importance of Fas could not be easily assessed in the adoptive-transfer
model because donor T cells failed to repopulate in Fas-mutant
lpr mice, perhaps because splenocytes from lpr
mice have upregulated FasL, which can be toxic for activated T cells
and therefore may have prevented their repopulation (37). Experiments with IFN- receptor knockout mice suggest that the ability of the non-virus-specific T cells to respond to IFN- plays a
significant role in inducing this susceptible state. T cells from
IFN- receptor-deficient mice are themselves somewhat resistant to
AICD (19), and we show here that this deficiency could not
be overcome by the presence of wild-type activated T cells. IFN- is
reported to upregulate Fas expression, and this may in part explain its
role in sensitizing cells to apoptosis (18, 19).
Other factors may also be involved in this bystander sensitization to
apoptosis, including interleukin-2 (IL-2), which would be produced by
the virus-specific activated T cells. After exposure to high
concentrations of IL-2, murine Th1 clones or lymph node T cells undergo
apoptosis on TCR ligation (15). The data presented here do
not directly address the role of IL-2 in bystander sensitization to
AICD, but we have previously shown in the LCMV system that in vitro
exposure to IL-2 greatly augments the sensitization of T cells to AICD
(25). It is also noteworthy that IL-2 can induce the
synthesis of IFN-, which itself may regulate apoptosis
(19).
During acute infections of humans and animals with many viruses, there
is a transient period in which the ability to mount a T-cell response
to other antigens is severely compromised (27, 35). The
results detailed here suggest a mechanism by which those T cells not
responding to the virus become sensitized, in a bystander fashion, to
undergo AICD on receptor triggering. This period when the T cells are
susceptible to AICD is transient, because the ability to respond to
recall antigens returns after the acute phase of the antiviral immune
response has passed. Careful quantification of memory cytotoxic
T-lymphocyte precursors, however, has recently revealed that acute
viral infections can cause significant and permanent reductions in the
total number of T cells specific to viruses from previous infections
(30). In addition, studies have shown that the total numbers
of T cells not specific for LCMV decline by 30 to 50% during an acute
LCMV infection, and such reductions are greatest in bystander T cells
expressing the CD44 activation/memory marker (38;
J. M. McNally, C. C. Zarozinski, and R. M. Welsh, FASEB
J. 13:982, 1999, abstract). Thus, T cells not specific for a
virus may become destabilized, possibly in the FasL-rich environment,
and undergo some attrition even in the absence of high-affinity
receptor stimulation, but in the presence of strong ligands they may
quickly undergo apoptosis. TNF-TNF receptor interactions can sometimes
substitute for Fas-FasL interactions in the AICD of CD8 T cells
(16), and it would be interesting to explore the role of
that receptor-ligand pair in this system. It is noteworthy that after
clearance of virus, the overall T-cell numbers decline normally in an
environment lacking Fas or FasL (17, 24), but this is
probably due to a distinctly different mechanism from AICD and is
probably related to removal of growth and survival factors for
activated lymphocytes.
Bystander sensitization to apoptosis may also be a mechanism for immune
deficiencies associated with persistent viral infections and autoimmune
conditions involving chronic T-cell responses. In HIV infection, the
immune response is chronic, and the T cells are in an environment in
which there is a continual T-cell response threatening attrition of
other cells. The T cells undergoing apoptosis in HIV- and SIV-infected
lymph nodes are predominantly uninfected bystander cells
(4). Previous work has shown that CD8+ T cells
from HIV-infected asymptomatic individuals respond poorly to anti-CD3
stimulation in vitro and undergo apoptosis (8, 33) and that
CD8+ T cells derived from asymptomatic HIV-positive
individuals were in a "preapoptotic" state in vivo and could
undergo apoptosis after overnight culture in media (17). Our
work presented here is consistent with those results and indicates in a
defined experimental system that uninfected bystander cells that are
clearly not virus specific can become destabilized in the environment
of an activated T-cell response.
| |
ACKNOWLEDGMENTS |
We thank Barbara Fournier and Tammy Krumpoch for running the FACS
samples and Ralph Budd for the TUNEL protocol.
This work was supported by USPHS research grant AI17672 to R.M.W. and
training grant AI07349 to C.C.Z.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology, University of Massachusetts Medical Center, 55 Lake Ave.
North, Worcester, MA 01655. Phone: (508) 856-5819. Fax: (508) 856-5780. E-mail: raymond.welsh{at}umassmed.edu.
Present address: Department of Microbiology and Molecular Genetics,
Harvard Medical School, Boston, MA 02155.
Present address: California Regional Primate Research Center,
University of California, Davis, CA 95615.
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Top
Abstract
Introduction
