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Infection and Immunity, August 2000, p. 4470-4476, Vol. 68, No. 8
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Adaptive Immunity against Listeria monocytogenes in
the Absence of Type I Tumor Necrosis Factor Receptor
p55
Douglas W.
White,1
Vladimir P.
Badovinac,2
Xin
Fan,3 and
John T.
Harty1,2,*
Interdisciplinary Graduate Program in
Immunology1 and Department of
Microbiology,2 University of Iowa, Iowa
City, Iowa 52242, and Department of Microbiology, University of
Pennsylvania School of Medicine, Philadelphia, Pennsylvania
191043
Received 23 November 1999/Returned for modification 14 February
2000/Accepted 2 May 2000
 |
ABSTRACT |
Tumor necrosis factor (TNF) and the type I TNF receptor
(TNFRI), p55, are critical for resistance against primary
infections with the intracellular bacterial pathogen Listeria
monocytogenes. Importantly, however, susceptibility to
primary listeriosis in cytokine-deficient mice does not preclude the
development or expression of effective adaptive immunity against
virulent L. monocytogenes. We used
TNFRI
/ mice to study adaptive
antilisterial immunity in the absence of interactions between TNF
and TNFRI. Our experiments indicate that
TNFRI/ mice survive and clear high-dose
challenges with an attenuated strain of L. monocytogenes
that is incapable of cell-to-cell spread. Furthermore,
TNFRI/ mice immunized with attenuated
L. monocytogenes go on to develop potent adaptive immunity
to subsequent high-dose challenges with virulent L. monocytogenes. Interestingly, CD8+ T-cell depletion
in vivo inhibits immunity to L. monocytogenes in the spleen
but not in the liver of TNFRI/ mice. The
adaptive immune response in these animals is characterized by
activation of listeriolysin O-specific CD8+ T cells, which
are capable of transferring antilisterial immunity to naive wild-type
C57BL/6 host mice. These experiments demonstrate the development and
expression of potent CD8+ T-cell-mediated antilisterial
immunity in the absence of TNFRI.
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INTRODUCTION |
A number of cytokine and cytokine
receptor deficiencies have been described which render mice more or
less susceptible than wild-type animals to primary infection with the
intracellular bacterial pathogen Listeria monocytogenes
(13, 40). These studies have helped establish the importance
of cytokines in the innate immune response to infection with
L. monocytogenes. Tumor necrosis factor (TNF) and the
type I TNF receptor (TNFRI), p55, comprise a cytokine-cytokine
receptor pair that is clearly important in the normal immune response
to L. monocytogenes. TNF is produced shortly following
infection with L. monocytogenes, and neutralization of TNF
with specific antibodies exacerbates listeriosis in mice (16, 17,
27). Administration of recombinant human TNF can also reduce the
severity of primary infection with L. monocytogenes in mice
(20, 33). The importance of this cytokine-receptor pair
during the primary immune response to L. monocytogenes was confirmed when TNF/ (28) and
TNFRI/ (9, 30, 34) mice were found
to be highly susceptible to primary listeriosis. More recently, a
functional death domain of TNFRI/ has been
shown to be required for antilisterial resistance (31).
The observation that TNF is critical during the early stages of the
immune response to L. monocytogenes suggests that cells involved in the innate immune response produce the requisite TNF. This
interpretation is further supported by studies in which nude (athymic)
mice (15) or SCID mice (2), which lack mature T cells, were rendered more susceptible to L. monocytogenes
infection by neutralization of TNF. A series of studies from Unanue's
group using SCID mice helped uncover the basis of innate immunity to L. monocytogenes and defined an axis of cytokine-driven
interactions between NK cells and macrophages which leads to the
activation of listericidal activity in macrophages and is
responsible for the early control of L. monocytogenes
replication in normal mice (40, 41). TNF is a key mediator
of macrophage activation in this process.
Importantly, susceptibility to primary listeriosis does not necessarily
correlate with susceptibility to a secondary challenge (14).
In fact, the most pronounced immunodeficiency described to date, as
measured by susceptibility to primary challenge with virulent L. monocytogenes, occurs in mice with a targeted disruption of the
gamma interferon (IFN-
) gene. The 50% lethal dose
(LD50) of virulent L. monocytogenes in these
animals is approximately 10 CFU (12). However, adaptive
immunity can be elicited by immunization with attenuated L. monocytogenes, which confers resistance in IFN-/ mice to high-dose challenges with virulent
L. monocytogenes (12).
In addition to its role in the innate response, neutralization studies
suggested that TNF is important during a secondary response to L. monocytogenes in wild-type mice (35). This suggested that TNF, produced by cells of the adaptive immune system, may be
involved in adaptive immunity to L. monocytogenes. Since
CD8+ T cells readily produce TNF in response to
antigen-specific stimulation and since CD8+ T cells
are important mediators of adaptive immunity to L. monocytogenes, we hypothesized that TNF-TNFRI
interactions might be required in adaptive immunity to L. monocytogenes. This hypothesis was further suggested by
experiments showing that CD8+ T cells from perforin
knockout mice provide antilisterial immunity in hosts with depleted
IFN- but fail to do so in hosts with depleted TNF (43).
In the present studies, we used attenuated L. monocytogenes
to immunize TNFRI/ mice and study adaptive
immunity to L. monocytogenes in the absence of interactions
between TNF and TNFRI. We provide evidence that neither the
development nor the expression of adaptive immunity to L. monocytogenes requires TNFRI. We further demonstrate
that, at least in the spleen, adaptive immunity to L. monocytogenes in TNFRI/ mice
requires CD8+ T cells, indicating that CD8+
T-cell-mediated immunity to L. monocytogenes in the spleen
can function independently of TNFRI.
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MATERIALS AND METHODS |
Mice.
C57BL/6 (B6, H-2b major
histocompatibility complex [MHC]) mice were obtained from the
National Cancer Institute (Frederick, Md.). TNFRI-deficient
(TNFRI/) mice (30) were the kind
gift of Amgen, Inc., Toronto, Canada. B6 and
TNFRI/ mice were housed at the University of
Iowa animal care unit. Mice were matched for age and sex and used at 8 to 16 weeks of age.
Bacteria.
Virulent L. monocytogenes strains
10403s (4) and XFL204, attenuated L. monocytogenes strains DP-L1942 (ActA) (5)
and DP-L1936 (PlcAB) (38), and
Salmonella enterica serovar Typhimurium strain SL1344 (18) are all resistant to streptomycin. Recombinant L. monocytogenes XFL204 was kindly provided by H. Shen, University of
Pennsylvania. XFL204 is derived from 10403s and was engineered using
previously described strategies (37) to secrete a fusion
protein consisting of dihydrofolate reductase and amino acids 396 to
404 of the nucleoprotein (NP) of lymphocytic choriomeningitis virus
(LCMV) (X. Fan, unpublished data). NP396-404 is a well-characterized
H-2Db-restricted CD8+ T-cell epitope
from LCMV (42). Frozen stocks of bacteria were diluted in
TSB and grown in a bacterial shaker at 37°C to an optical density at
600 nm of approximately 0.1 (approximately 108 CFU/ml),
diluted in pyrogen-free saline (Abbott Laboratories, North Chicago,
Ill.), and injected intravenously (i.v.) or intraperitoneally (i.p.) as
indicated in 0.2-ml volumes per animal. Aliquots were plated onto
tryptic soy agar containing 50 µg of streptomycin per ml (TSA-Strep)
to verify the number of CFU injected.
Cell lines and cell culture.
EL4 is a C57BL/6-derived
thymoma cell line (H-2b MHC; ATCC TIB-39);
EL4-LLO refers to EL4 cells stably transfected with a plasmid construct
expressing listeriolysin O (LLO) and G418 resistance (11).
Cell lines were maintained in RPMI 1640 (Gibco BRL, Grand Island, N.Y.)
supplemented with 10% fetal calf serum, 100 U of penicillin per ml,
100 µg of streptomycin per ml, 50 µg of gentamicin per ml, 10 mM
HEPES, 2 mM L-glutamine, and 50 µM 2-mercaptoethanol (RP10). Transfected cells were maintained in RP10 supplemented with 400 µg of G418 per ml.
Hybridomas and monoclonal Abs.
Our studies utilized the
following monoclonal antibodies (Abs), which were purified from
hybridoma supernatants: rat anti-mouse CD8 (2.43 [36])
and rat anti-mouse CD4 (GK1.5 [7]). Control polyclonal
rat immunoglobulin G (IgG) was purchased from Sigma (St. Louis, Mo.).
Monoclonal Abs were purified from culture supernatants using protein G
affinity chromatography as recommended by the manufacturer (Pharmacia).
Protein concentrations were determined using the bicinchoninic acid
assay (Pierce). Flow cytometric analysis was performed using
fluorescein isothiocyanate-conjugated anti-CD8 (53.6-7) (Sigma)
and phycoerythrin PE-conjugated anti-CD4 (H129.19) (Sigma).
T-cell subset depletion in vivo was carried out by injecting mice i.p.
with a total of 1 mg of 2.43, GK1.5, or control rat IgG per animal in
divided doses for two or three consecutive days prior to L. monocytogenes challenge (12). CD8+ and
CD4+ T-cell subset depletions were quantitated by flow
cytometry by dividing the percentage of cells in the relevant subset of
a depleted spleen by the percentage of cells in the same subset in a
control Ig-treated spleen.
Generation and maintenance of CD8+ T-cell lines.
H-2b MHC CD8+ T-cell lines specific
for LLO were derived from B6 mice and H-2b
TNFRI/ mice and were restimulated with
EL4-LLO cells. A total of 2 × 107 to 4 × 107 splenocytes from mice injected 7 to 10 days previously
with the indicated dose of virulent L. monocytogenes 10403s
or attenuated L. monocytogenes DP-L1942 were incubated with
3 × 106 irradiated (150 Gy) EL4-LLO stimulator cells
in RP10 at 37°C under 7% CO2. In some experiments (as
indicated), infected mice were treated i.p. with ampicillin at 2 mg/mouse/day on days 1 to 3 postinfection. For T-cell lines specific
for NP396-404, EL4 cells supplemented with 100 nM synthetic NP396-404
were used as stimulators. Subsequent weekly restimulations were carried
out by combining 3 × 106 to 5 × 106
responder cells with 3 × 106 irradiated (150 Gy)
stimulator cells and approximately 4 × 107 irradiated
(30 Gy) syngeneic splenocytes in RP10 supplemented with 5% supernatant
from concanavalin A-stimulated rat spleen cells and 50 mM
-methylmannoside.
51Cr release assays.
51Cr release
assays were performed by labeling 1.1 × 106 target
cells (EL4 or EL4-LLO) for 1 h at 37°C under 7% CO2
in 0.2 ml of RP10 with 100 µCi of sodium [51Cr]
chromate (NEN, Boston, Mass.) and rinsing them three times with 10 ml
of phosphate-buffered saline. Then 104 labeled target cells
per well were combined with effector cells at the indicated ratios in
RP10 in round-bottom 96-well plates. Following a 4-h incubation,
supernatant was harvested and assayed for 51Cr release in a
gamma counter (Wallac, Turku, Finland). Spontaneous and total release
were determined by incubating target cells alone in RP10 or 0.5%
Triton X-100, respectively. The percent specific release of
51Cr was calculated by the formula 100 × (experimental cpm 
spontaneous cpm)/(total cpm spontaneous cpm). Spontaneous release was less than 15% of total in
all assays.
Adoptive transfer experiments.
The capacity of
CD8+ T cells to mediate antilisterial immunity in vivo was
quantitated using adoptive-transfer assays. CD8+ T cells
restimulated in vitro 7 to 9 days previously were harvested, washed in
antibiotic-free buffer, and resuspended in pyrogen-free saline. The
cells were delivered i.v. in 0.2- to 0.5-ml volumes into naive host
mice. Within 2 h, host mice, including uninjected controls, were
challenged i.v. with the indicated dose of bacteria. The numbers of CFU
per spleen and per liver were determined 3 days postchallenge by
homogenizing the spleens and livers in 0.2% IGEPAL (Sigma), plating
10-fold serial dilutions onto TSA-Strep and calculating mean colony
counts after overnight incubation at 37°C. Data are presented as mean
log10 CFU ± standard deviation per spleen or per gram
of liver. Student's t test was used in statistical
analysis; P values are shown for each group compared to
the control group in the same experiment which did not receive protective T cells.
Survival assays.
The susceptibility of different strains of
mice to infection with virulent L. monocytogenes was
quantitated by estimating the lethal dose of 10403s in 50% of the
animals (LD50) by the method of Reed and Muench
(32).
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RESULTS |
Estimation of the LD50 of virulent L. monocytogenes 10403s in TNFRI/
mice.
Previous studies have demonstrated that
TNFRI/ mice succumb to primary infection with
low doses of virulent LM (250 to 500 CFU) that are sublethal for
wild-type mice (9, 30, 34). It was of interest to estimate
the lower limit of susceptibility of these animals to virulent
L. monocytogenes and to explore the possibility that
very low challenges (<250 CFU) with virulent L. monocytogenes might cause chronic but nonlethal infections in TNFRI/ animals. To estimate the
LD50 of virulent L. monocytogenes 10403s in
TNFRI/ mice, naive TNFRI/
animals were injected i.v. with graded doses of 10403s and
monitored for survival. CFU analyses were performed in triplicate on
the bacterial suspensions which were used to inject the mice. These indicated that 80 to 115% of the expected dose was delivered. Whereas
all wild-type B6 mice that received 103 CFU of virulent
L. monocytogenes survived at least 27 days, all TNFRI/ mice that received the same dose of
virulent L. monocytogenes died within 8 days of
challenge. Within 11 days, 43% (3 of 7) of the
TNFRI/ mice that received 102 CFU
of virulent L. monocytogenes had died. All
TNFRI/ mice that were challenged with
101 CFU of virulent L. monocytogenes survived at
least 27 days. These results reveal that the LD50 of
virulent L. monocytogenes 10403s in naive
TNFRI/ is approximately 102.
The LD
50 of virulent strain 10403s administered i.v. to B6
mice was approximately 10
4.7 (data not shown). Thus,
compared to wild-type mice, TNFRI
/ mice are
highly susceptible to primary infection with virulent
L. monocytogenes. The LD
50 of 10403s is approximately
500-fold
lower in TNFRI
/ mice than in
wild-type
animals.
Chronic
L. monocytogenes infection in immunocompromised mice
has been observed previously (
1,
23,
40). To test whether
TNFRI
/ mice are susceptible to chronic
infections with virulent
L. monocytogenes,
all surviving
mice were sacrificed at 27 or 33 days postchallenge
and examined for
the presence of
L. monocytogenes. CFU analysis
performed on spleen and liver homogenates with limits of detection
of
50 CFU/spleen and 100 CFU/g of liver failed to detect persistent
L. monocytogenes infection in any
mice.
These results verify the extreme susceptibility of
TNFRI
/ to primary challenge with virulent
L. monocytogenes compared to that
of control B6 mice.
Additionally, the data indicate that
TNFRI
/ mice can clear infections with
small numbers of virulent
L. monocytogenes,
since there
was no evidence of chronic infection in
TNFRI
/ mice that survived near-lethal
challenges.
TNFRI/ mice survive high-dose challenges
with an attenuated strain.
Secondary immunity to L. monocytogenes is mediated most efficiently by CD8+ T
cells in wild-type and IFN-/ mice (12,
13). The susceptibility of TNFRI/ mice
to primary L. monocytogenes infection suggests that
immunization of these mice using virulent L. monocytogenes
may be problematic since necessarily low (and therefore highly variable
with respect to the LD50) challenge doses of virulent
L. monocytogenes may not adequately or consistently
prime T-cell responses. To determine the feasibility of immunizing
TNFRI/ mice with attenuated L. monocytogenes, two attenuated strains, DP-L1942 (5) and
DP-L1936 (38), were used at high doses to challenge
TNFRI/ mice. DP-L1942 carries an engineered
in-frame deletion in the actA gene, which encodes a protein
involved in actin polymerization and cell-to-cell spread (8,
22). DP-L1942 is effective for immunization of
IFN-/ mice and activates the CD8+
T-cell compartment in IFN-/ and wild-type mice
(10, 12). DP-L1936 carries an engineered in-frame
deletion in the genes for phospholipases A and B (plcA and
plcB), which are involved in the escape of the bacterial
cell from the primary (plcB) and secondary (plcA
and plcB) phagosomes (38, 39). Both DP-L1942 and
DP-L1936 are attenuated in wild-type mice, with LD50s of
approximately 107 and 106.5,
respectively (5, 38). TNFRI/ and
B6 mice were challenged with high doses of both attenuated strains and
monitored for survival (Table 1). Whereas
all of the animals survived high-dose challenge with DP-L1942, all
TNFRI/ mice challenged with 106
CFU of DP-L1936 succumbed to infection. Mortality was also observed with DP-L1936 at doses as low as 104 CFU per animal.
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TABLE 1.
TNFRI/ mice survive high-dose
challenges with attenuated L. monocytogenes DP-L1942
(actA) but are more susceptible than B6 mice to attenuated
DP-L1936 (plcAB)a
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In a separate experiment, one of three TNFRI
/
mice had detectable
L. monocytogenes (~10
3 CFU
per spleen and per g of liver) at 7 days after infection
with
10
6 CFU DP-L1942 while none of three wild-type B6 mice had
detectable
organisms (limit of detection, 100 CFU/organ). The levels of
L. monocytogenes were below these limits in
TNFRI
/ mice at 10 days after infection with
10
6 CFU of DP-L1942. Similar results, indicating a slight
delay in
clearance of DP-L1942 in immunocompromised mice, were
found with
IFN-
/ mice (V. P. Badovinac,
A. Tvinnereim, and J. T. Harty, submitted
for publication).
However, in all cases examined to date, clearance
of the
actA mutant was complete by 10 days postinfection (p.i.).
This is consistent with the course of sublethal
L. monocytogenes infections in wild-type mice, which are cleared by
approximately
10 days p.i. In contrast, chronic infections are observed
in SCID
mice, which lack adaptive immune systems (
3), and
slp-76
/ mice, which lack T cells (
26). Thus,
the results with DP-L1942
are consistent with those of previous studies
in wild-type and
IFN-
/ mice and indicate that (i)
clearance of attenuated LM DP-L1942
from
TNFRI
/ mice is rapid and complete and (ii)
immunization of TNFRI
/ mice results in an
adaptive immune response which may provide
protection against secondary
challenges with virulent
LM.
Antigen-specific adaptive immunity to virulent L. monocytogenes in TNFRI/ mice.
Survival of TNFRI/ mice following high-dose
challenge with attenuated L. monocytogenes might only
reflect the activity of the innate immune response and does not
demonstrate the development of secondary immunity. To test whether
a high-dose challenge with attenuated L. monocytogenes
DP-L1942 leads to the development of secondary resistance in
TNFRI/ mice, naive and DP-L1942-immunized
TNFRI/ mice were challenged with graded doses
of virulent strain 10403s and monitored for survival (Table
2). Naive and immunized B6 animals were
included as controls. Consistent with the experiments described above,
all naive TNFRI/ mice challenged with 2 × 103 CFU of virulent L. monocytogenes died
within 8 to 9 days of challenge. In contrast, all
TNFRI/ mice that had been previously
immunized with 106 CFU of attenuated strain DP-L1942
survived challenges with 2 × 105 CFU of virulent
strain 10403s. Four of five of the immunized TNFRI/ mice (80%) survived challenges
with 2 × 106 CFU of virulent L. monocytogenes, and one of three TNFRI/
mice (33%) survived challenge with 10-fold more L. monocytogenes CFU. These data indicate that resistance to
virulent strain 10403s in TNFRI/ mice
undergoing secondary challenge is at least 10,000-fold greater than resistance to this strain in naive
TNFRI/ mice.
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TABLE 2.
Previously immunized TNFRI/
mice exhibit high levels of resistance to secondary challenge with
virulent L. monocytogenesa
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To examine the severity of infection in naive and immune
TNFRI
/ mice challenged with virulent
L. monocytogenes, CFUs in the spleen
(Fig.
1A) and the liver (Fig.
1B) were measured
3 days after a
high-dose challenge with virulent strain 10403s.
TNFRI
/ mice that had been previously
immunized with attenuated
L. monocytogenes showed dramatic
reductions in CFUs in both the spleen and the
liver compared to naive
animals. Immune TNFRI
/ mice and immune B6
mice were equally capable of controlling secondary
infection with
virulent
L. monocytogenes by day 3 p.i. Both B6
and
TNFRI
/ mice that had not been previously
exposed to attenuated
L. monocytogenes suffered severe
listeriosis in the spleen and liver, with high
levels of infection.
Interestingly, while the primary infection
in the livers of naive
TNFRI
/ mice (10
9.5 CFU) was more
severe than the primary infection in the livers
of naive B6 mice
(10
7.4 CFU), there was no apparent difference in the
severity of primary
infection in the spleen. However, with lower doses
of virulent
L. monocytogenes administered i.p., a more
severe infection has
been observed in both the spleens and the livers
of naive TNFRI
/ mice than in those of naive
B6 mice 3 days following primary
infection (
9). Combined
with the survival studies, these results
demonstrate that immunization
of TNFRI
/ mice with attenuated
L. monocytogenes leads to the development
of adaptive immunity to
high-dose challenges with virulent
L. monocytogenes.
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FIG. 1.
Immunized TNFRI/ mice
exhibit high levels of resistance to secondary challenge with virulent
L. monocytogenes. B6 or TNFRI/
(RI/) mice, which were naive or had been immunized i.p. with
106 CFU attenuated L. monocytogenes DP-L1942 28 days previously, were challenged i.v. with 1.7 × 105
CFU of virulent strain 10403s. CFUs in the spleen (A) and liver (B)
were measured 3 days later. Data are presented as mean
log10 CFU and standard deviation for two to four mice per
group. Student's t test was used to calculate P
values. These data are representative of two independent experiments
with similar results.
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To verify the antigen specificity of secondary resistance to
L. monocytogenes in TNFRI
/
mice, groups of five to seven TNFRI
/ mice
were immunized with 10
6 CFU of attenuated strain DP-L1942
and 7 weeks later the immune
mice and naive controls were challenged
with 10
4 CFU of virulent
L. monocytogenes 10403s
or 10
2 CFU of the unrelated bacterium
S. enterica serovar Typhimurium
SL1344 (
18). All the
animals were then monitored for survival.
Consistent with the data in
Table
2, five of five immunized TNFRI
/ mice
survived challenge with virulent strain 10403s while six
of six naive
TNFRI
/ mice challenged with virulent strain
10403s died. Immune mice
were not resistant to challenge with virulent
S. enterica serovar
Typhimurium SL1344, since all seven of
these mice also succumbed.
Similarly, five of six naive
TNFRI
/ mice challenged with virulent
S. enterica serovar Typhimurium
SL1344
died.
These results indicate that immunization of
TNFRI
/ mice with attenuated
L. monocytogenes does not result in resistance, as
measured by
survival, to an unrelated intracellular bacterial
pathogen. Since the
LD
50 of SL1344 in wild-type mice is very low
(~25
organisms) (
29), we did not perform a direct comparison
of
the virulence of this organism in naive wild-type versus naive
TNFRI
/ mice.
These data are also consistent with other experiments (results not
shown) in which TNFRI
/ mice remain resistant
to high-dose challenges with virulent
L. monocytogenes for
up to 16 weeks after immunization with DP-L1942.
Thus, clearance of
DP-L1942 by TNFRI
/ mice not only is rapid and
complete but also results in long-lasting
immunity to challenges with
otherwise lethal doses of virulent
L. monocytogenes.
CD8+ T cells in TNFRI/ mice
respond in an antigen-specific fashion following immunization with
L. monocytogenes.
Since the CD8+ T-cell response
plays an important role in adaptive antilisterial immunity in wild-type
mice (25), it was of interest to determine whether a
CD8+ T-cell response develops in
TNFRI/ mice following infection with L. monocytogenes. Wild-type or perforin-deficient
H-2b mice infected with L. monocytogenes mount H-2Kb-restricted
CD8+ T-cell responses to LLO, a protein antigen
secreted by L. monocytogenes (11). Splenocytes
from TNFRI/ mice, previously immunized with
106 CFU of attenuated strain DP-L1942, were restimulated in
vitro with irradiated syngeneic stimulator EL4-LLO cells. Following two
restimulations in vitro, these effector cells (which were 98%
CD4 CD8+ by flow cytometric analysis [data
not shown]) were tested for antigen-specific cytolytic
activity in a standard 51Cr release assay (Fig.
2).
TNFRI/-derived CD8+ T cells
specific for LLO efficiently lysed target cells in an antigen-specific
fashion. These results indicate that L. monocytogenes infection in TNFRI/ mice activates
LLO-specific CD8+ T cells.
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FIG. 2.
CD8+ T cells from L. monocytogenes-immunized TNFRI/ mice
exhibit antigen-specific cytolysis of target cells expressing LLO.
LLO-specific CD8+ T cells derived from
TNFRI/ mice (squares) or B6 mice (circles)
were incubated at the indicated effector-to-target ratio (E:T) with
51Cr-labeled EL4 (open symbols) or 51Cr-labeled
EL4-LLO (solid symbols) cells for 3.5 h. Specific lysis was
determined by measuring 51Cr in the supernatant by standard
techniques. These data are representative of two independent
experiments with similar results.
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One limitation of our studies of listeriosis in
TNFRI
/ mice (which bear MHC molecules of the
H-2b haplotype) is that no endogenous MHC class
Ia-restricted CD8
+ T-cell epitopes have been defined in the
H-2b system. It was of interest to measure the
CD8
+ T-cell response in TNFRI
/
mice against a defined
H-2b-restricted epitope.
Toward that end, TNFRI
/ and B6 mice were
immunized with high doses of virulent
L. monocytogenes XFL204. Strain XFL204 secretes a fusion protein containing a known
H-2Db-restricted CD8
+ T-cell epitope
derived from the nucleoprotein of LCMV (NP396-404)
(H. Shen et al.,
unpublished data). Challenge doses of XFL204
in B6 and
TNFRI
/ mice were normalized to approximately
10 LD
50 (data not shown).
To allow survival of the animals
following high-dose challenge
with virulent strain XFL204, the animals
were injected i.p. with
ampicillin (2 mg/animal/day) on days 1 to
3 p.i. All B6 and TNFRI
/ animals
subjected to this regimen survived for at least 1 week
post challenge.
At 7 days postchallenge, splenocytes from each
animal were cultured in
vitro with the NP396-404 peptide. Following
6 days of restimulation in
vitro, responders were analyzed for
antigen-specific cytolytic activity
in a standard
51Cr release assay (Fig.
3). The results reveal
NP396-404-specific
CD8
+ T-cell expansion and cytolytic
activity in all animals, regardless
of genotype, subjected to primary
infection with a high dose of
virulent
L. monocytogenes
XFL204 and given antibiotic therapy.
The
51Cr release assay
used in these experiments is not sufficiently
quantitative to conclude
that differences in the level of response
are significant.
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FIG. 3.
Antigen-specific expansion of CD8+ T cells
in TNFRI/ mice following high-dose challenge
with virulent L. monocytogenes. Wild-type B6 (A) or
TNFRI/ (B) mice were injected with
approximately 10 LD50 of virulent L. monocytogenes XFL204 (105 in B6 mice and
103 in TNFRI/ mice) followed by a
3-day course of antibiotic therapy. At 7 days postchallenge,
splenocytes were harvested from each animal and were cultured in vitro
with irradiated EL4 cells and NP396-404 at 100 nM. After 6 days in
vitro, responders were incubated at the indicated dilutions with
51Cr-labeled EL4 cells in the absence (open symbols) or
presence (solid symbols) of NP396-404 at 100 nM for 4 hours. Each line
represents an independent animal.
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LLO-specific CD8+ T cells derived from
TNFRI/ mice transfer potent antilisterial
immunity to naive wild-type B6 host mice.
LLO-specific
CD8+ T cells from wild-type B6 mice mediate potent
antilisterial immunity in adoptive-transfer assays (11, 43). To assess the ability of LLO-specific CD8+ T cells derived
from TNFRI/ mice to mediate antilisterial
immunity, naive B6 host mice were injected i.v. with LLO-specific
CD8+ T cells from TNFRI/ mice and
then given a high-dose challenge with virulent L. monocytogenes 10403s. CFU analyses of spleen and liver homogenates
were performed 3 days postchallenge to assess the level of infection in
T-cell-injected mice and in noninjected control animals (Table
3). The results show that LLO-specific
CD8+ T cells from TNFRI/ mice
mediated dramatic reductions in L. monocytogenes CFU in both
the spleens and the livers of recipient animals. Multiple experiments
have demonstrated previously that similar reductions in CFUs correlate
with the survival of T-cell-injected animals whereas unprotected mice
die 4 to 6 days after a challenge with similar doses of virulent
L. monocytogenes 10403s (43, 44). Thus,
LLO-specific CD8+ T cells from
TNFRI/ mice mediate antilisterial immunity in
naive B6 host mice.
Adaptive immunity to L. monocytogenes in
TNFRI/ mice involves CD8+ T
cells.
While both CD4+ and CD8+ T cells
respond in an antigen-specific fashion to infection with virulent
L. monocytogenes, adoptive-transfer experiments (4, 6,
24) and studies in mice deficient in CD4+ or
CD8+ T cells (21, 25) indicate that
CD8+ T cells are the most effective mediators of specific
antilisterial immunity in wild-type mice. To determine whether
CD8+ T cells play a role in the expression of secondary
immunity to L. monocytogenes in the absence of
TNFRI, TNFRI/ mice were immunized
with attenuated L. monocytogenes DP-L1942 and allowed to
rest for at least 28 days; then the CD4+ or
CD8+ T cells of the mice were depleted with injections of
depleting monoclonal Ab, and the mice challenged with virulent L. monocytogenes. At 3 days postchallenge, CFU analyses were
performed to determine bacterial loads in the spleen and liver. In
addition, a subset of animals from each group was monitored for
survival for 14 days (see below). Results of CFU analyses indicate that
depletion of CD8+ cells exacerbated infection in the
spleens (Fig. 4A) but not significantly
in the livers (Fig. 4B) of TNFRI/ mice
undergoing a secondary response to L. monocytogenes.
Depletion of CD4+ cells, in contrast, did not result in
increased bacterial loads in either the spleen (Fig. 4A) or the liver
(Fig. 4B).
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|
FIG. 4.
Depletion of CD8+ T cells, but not
CD4+ T cells, diminishes secondary immunity to L. monocytogenes in the spleen in TNFRI/
mice. Five to six TNFRI/ mice per group were
immunized i.p. on day 0 with 106 CFU of attenuated L. monocytogenes DP-L1942. On day 30 to 32, immune mice received
control polyclonal rat IgG (rIgG), rat anti-mouse CD8 (CD8), or rat
anti-mouse CD4 (CD4) as indicated at 0.3 mg/mouse/day i.p. On day
33, all mice were challenged i.v. with 106 CFU of virulent
strain 10403s. At 3 days p.i., the animals were sacrificed and analyzed
for CFU in the spleen (A) and liver (B). The efficiency of in vivo
depletion averaged 86 and 91% for CD8+ and
CD4+ cells, respectively, as determined by flow cytometric
analysis of splenocytes. These data are pooled from two independent
experiments and are given as mean and SD. NS, not significant.
|
|
| |
DISCUSSION |
Adaptive immunity to L. monocytogenes in the absence of
TNFRI.
The requirement for TNF and TNFRI in
the primary response to L. monocytogenes has been
established previously (9, 28, 30, 34). In the
experiments described above, we estimate the LD50 of
virulent L. monocytogenes 10403s in naive
TNFRI/ mice to be approximately
102, compared to approximately 104.7 in
wild-type mice. The extreme susceptibility of these mice to primary
listeriosis complicates studies of secondary resistance to L. monocytogenes since anything but the lowest immunizing dose (which
is difficult to estimate precisely at the time of immunization) is
lethal. This problem has been overcome previously in
IFN-/ mice by immunizing naive animals with an
attenuated strain of L. monocytogenes that does not
express the virulence factor encoded by the L. monocytogenes gene actA (12). This
strain, which invades host cells and escapes from the phagosome into
the cytoplasm but fails to spread from cell to cell, elicits
protective, CD8+ T-cell-dependent immunity in wild-type and
IFN-/ mice (12). Here we demonstrate the
versatility of this strategy and use it to study secondary immunity to
L. monocytogenes in TNFRI/ mice.
Our results also suggest the feasibility of another approach, which is to immunize susceptible mice with doses of virulent L. monocytogenes that would otherwise be fatal and prevent death by
reducing the bacterial load with antibiotics.
TNFRI
/ mice survive high-dose challenges with
attenuated
actA mutant strains and subsequently develop
wild-type levels of resistance
to secondary challenge with virulent
strains. Thus, neither the
development nor the expression of high
levels of adaptive immunity
to
L. monocytogenes requires
TNFRI in genetically deficient mice.
This is the second
instance (IFN-
being the first) of a cytokine
or cytokine receptor
being absolutely required for effective innate
immunity to
L. monocytogenes but nonessential for an effective
adaptive immune
response.
Role of CD8+ T cells in adaptive immunity to L. monocytogenes in TNFRI/
mice.
We directly assessed the role of CD8+ T
cells in adaptive immunity to L. monocytogenes in
TNFRI/ mice by depleting the CD8+
T cells of immune TNFRI/ mice prior to secondary
challenge with virulent L. monocytogenes. The
depletion of CD8+ T cells increased the severity of
secondary listeriosis in the spleens of
TNFRI/ mice (Fig. 4). We also demonstrated
that CD8+ T cells in the spleens of
TNFRI/ mice respond in an antigen-specific
fashion to L. monocytogenes (Fig. 2 and 3). Thus,
CD8+ T cells can mediate antilisterial immunity in the
spleen by a mechanism that is independent of TNFRI. The
dependence of antilisterial immunity on CD8+ T cells in the
spleens of TNFRI/ mice is consistent with
previous studies which showed that perforin plays a role in
CD8+ T-cell-mediated immunity to L. monocytogenes in the spleen (19, 43, 44).
Depletion of CD8
+ T cells diminishes secondary immunity to
L. monocytogenes in both the spleens and livers of wild-type
mice
(
25). In contrast, depletion of CD8
+ T
cells did not result in significant exacerbation of listeriosis
in the
livers of immune TNFRI
/ mice. These data
could result from differential depletion of
CD8
+ cells in
wild-type and TNFRI
/ mouse livers or less
dependence on CD8
+ T cells for antilisterial immunity in
the livers in the absence
of TNFRI. Preliminary evidence
revealed low or undetectable levels
of CD8
+ cells in the
livers of wild-type and TNFRI
/ mice at 28 days after infection with strain DP-L1942 (D. W. White,
A. Schlueter, and J. T. Harty, unpublished data), and thus the
CD8
+ T cells that participate in immunity in the livers of
wild-type
mice must be recruited from the peripheral pool. Since
the peripheral
pool of CD8
+ T cells in immune
TNFRI
/ mice was reduced considerably by the
antibody treatment, exacerbating
the infection in the spleen, the liver
results are most consistent
with a compensatory, CD8
+
T-cell-independent mode of resistance in
TNFRI
/ mice. As has been observed in
wild-type mice (
25), depletion
of CD4
+ T cells
had no impact on antilisterial immunity in either the
spleens or livers
of immune TNFRI
/ mice. It should be pointed
out that our data do not formally
rule out the possibility that
CD4
+ T cells are able to express some antilisterial
activity when
CD8
+ T cells are depleted in the
TNFRI
/ mice. Together, these data are
consistent with an organ-specific
compensatory mechanisms of
antilisterial immunity in mice lacking
TNF-TNFRI
interactions. Since this immunity does not depend on
CD4
+
or CD8
+ T cells, it may be mediated by altered macrophage
function or
perhaps by
T cells. Immunohistochemical studies to
characterize
the immune response in the livers of mice lacking TNF and
TNFRI
are under way to address these
issues.
Previous experiments in our laboratory showed that perforin-deficient
CD8
+ T cells failed to transfer antilisterial immunity into
hosts
depleted of TNF with neutralizing Ab (
43). One
hypothesis to
explain this result is that TNF must engage
TNFRI on the activated
CD8
+ T cell in vivo for it
to mediate antilisterial immunity in an
adoptive-transfer assay. Our
data demonstrate that TNFRI expression
on activated
CD8
+ T cells is not required for adoptive immunity to
L. monocytogenes.
Therefore, although TNF may be required
for the in vivo antilisterial
activity of CD8
+ T
cells, its direct action on activated CD8
+ T cells via
their TNFRI is not
required.
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grant AI36864 and
AI42767 (J.T.H.). D.W.W. is a trainee in the Medical Scientist
Training Program.
The expert technical assistance of Lori Gorton and Gail Mayfield
is greatly appreciated. We thank Amgen, Inc., Toronto, Canada, for
TNFRI/ breeders and Hao Shen, University of
Pennsylvania, for XFL204, which was constructed in the laboratory of
Jeff F. Miller in the Department of Microbiology and Immunology at UCLA
School of Medicine.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 3-512 Bowen
Science Building, Department of Microbiology, University of Iowa, Iowa City, IA 52242. Phone: (319) 335-9720. Fax: (319) 335-9006. E-mail: john-harty{at}uiowa.edu.
Editor:
S. H. E. Kaufmann
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Abstract
Introduction
