Previous Article | Next Article 
Journal of Virology, September 1998, p. 7440-7449, Vol. 72, No. 9
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
CD40 Ligand-Mediated Interactions Are Involved in
the Generation of Memory CD8+ Cytotoxic T Lymphocytes
(CTL) but Are Not Required for the Maintenance of CTL Memory
following Virus Infection
Persephone
Borrow,1,*
David F.
Tough,2
Danelle
Eto,1
Antoinette
Tishon,1
Iqbal S.
Grewal,3
Jonathan
Sprent,2
Richard A.
Flavell,3 and
Michael
B. A.
Oldstone1
Division of Virology, Department of
Neuropharmacology,1 and
Department of
Immunology,2 The Scripps Research Institute, La
Jolla, California 92037, and
Section of Immunobiology, Howard
Hughes Medical Institute Research Laboratories, Yale University
School of Medicine, New Haven, Connecticut 065103
Received 22 April 1998/Accepted 17 June 1998
 |
ABSTRACT |
CD8+ cytotoxic T lymphocytes (CTL) play a key role in
the control of many virus infections, and the need for vaccines to
elicit strong CD8+ T-cell responses in order to provide
optimal protection in such infections is increasingly apparent.
However, the mechanisms involved in the induction and maintenance of
CD8+ CTL memory are currently poorly understood. In this
study, we investigated the involvement of CD40 ligand (CD40L)-mediated
interactions in these processes by analyzing the memory CTL response of
CD40L-deficient mice following infection with lymphocytic
choriomeningitis virus (LCMV). The maintenance of memory
CD8+ CTL precursors (CTLp) at stable frequencies over time
was not impaired in CD40L-deficient mice. By contrast, the initial
generation of memory CTLp was affected. CD40L-deficient mice produced
lower levels of CD8+ CTLp during the primary immune
response to LCMV than did wild-type controls, despite the fact that the
LCMV-specific effector CTL response of CD40L-deficient mice was
indistinguishable from that of control animals. The differentiation of
naïve CD8+ T cells into effector and memory CTL
thus involves pathways that can be discriminated from each other by
their requirement for CD40L-mediated interactions. Expression of CD40L
by CTLp themselves was not an essential step during their expansion and
differentiation from naïve CD8+ cells into memory
CTLp; instead, the reduction in memory CTLp generation in
CD40L-deficient mice was likely a consequence of defects in the
CD4+ T-cell response mounted by these animals. These
results thus suggest a previously unappreciated role for CD40L in the
generation of CD8+ memory CTLp, the probable nature of
which is discussed.
| |
INTRODUCTION |
The CD40 ligand (CD40L) CD154 is a
glycoprotein that is transiently expressed at high levels on the
surface of CD4+ T cells when they are activated (2,
30, 39, 51, 53). This protein is also expressed (although at
lower levels) on a subset of CD8+ T cells following
activation (2, 28, 39, 53), and its expression has been
documented on several other cell types, including mast cells,
eosinophils, basophils, and B cells (reviewed in reference 66). CD40L is a member of the tumor necrosis factor
family (2) and binds to CD40, a member of the tumor necrosis
factor receptor family (60). The latter is expressed on a
variety of cell types with antigen-presenting cell function, including
B cells, dendritic cells, activated macrophages, follicular dendritic
cells, and endothelial cells (reviewed in reference
66). The fact that CD40L and CD40 are expressed in a
tightly controlled fashion on T cells and on many different cell
populations with which they interact suggests that CD40L-CD40
interactions are probably involved in the regulation of a number of
aspects of the immune response. This is becoming increasingly apparent
as research into the functions of this receptor-ligand pair progresses
(17, 22, 23, 38, 50).
CD40L-CD40 interactions were originally shown to play a key role in
thymus-dependent humoral immune responses, mediating cognate interactions between CD4+ T cells and B cells that are
essential for B-cell activation and differentiation, class switching,
germinal center formation, and the generation of B-cell memory
(reviewed in references 21 and
31). More recently, roles for CD40L-CD40
interactions in the development of other immune effector functions have
been described. For example, they have been shown to be of importance
in the inflammatory immune response, regulating the induction of
secretion of cytokines, such as tumor necrosis factor alpha,
interleukin-1, interleukin-12, and gamma interferon (IFN-
), and of
nitric oxide by monocytes and macrophages and prolonging the survival
of these cells at sites of inflammation (reviewed in references
23 and 61). In addition,
CD40L-CD40 interactions have been shown to be involved in the
initiation of antigen-specific CD4+ T-cell responses
(24, 25, 65, 71). A current model for the role of this
system argues that CD40L is upregulated upon activation of
CD4+ T cells following recognition of antigen presented by
dendritic cells. CD40L then interacts with CD40 on the dendritic cell
surface, leading to the induction of costimulatory activity mediated by both cell surface molecules and cytokines such as interleukin-12 by the
dendritic cell (11, 35). This costimulatory activity is
necessary for the CD4+ T cell to become fully activated and
produce cytokines and/or perform other effector functions (reviewed in
references 22 and 23). Further,
CD40 is also expressed on thymic antigen-presenting cells
(19), and it has been demonstrated that CD40-CD40L
interactions play an essential role in negative selection in the thymus
(18). Here too, they likely act by regulating costimulatory
activity on antigen-presenting cells.
Despite the advances made recently in understanding the importance of
CD40L-CD40 interactions in the activation and effector functions of
mature CD4+ T cells, the functions of this receptor-ligand
pair are by no means fully understood. CD40L is likely involved in
other interactions between CD4+ T cells and the increasing
number of different cell types on which CD40 expression is being
documented; in addition, the role(s) that CD40L plays in the activation
and/or effector functions of the subpopulation of CD8+ T
cells that express it is not well defined. Human CD8+
T-cell clones expressing high levels of CD40L were shown to be able to
stimulate B-cell growth and differentiation in vitro (29), but the level of CD40L expressed by CD8+ T cells is
generally low, and the contribution made by CD8+ T cells to
cognate B-cell help during in vivo immune responses is not likely to be
very significant (54). The in vivo functions of CD40L
expression on CD8+ T cells thus remain unclear.
To gain further insight into the potential roles of CD40L in the in
vivo immune responses of both CD4+ and CD8+ T
cells, we have been analyzing the immune response mounted by CD40L-deficient mice (70) after infection with different
viruses. In a previous study (6), we found that although the
effector CD8+ cytotoxic T lymphocyte (CTL) response
mounted by CD40L-deficient mice on infection with arenaviruses
such as lymphocytic choriomeningitis virus (LCMV) was unimpaired and
virus clearance occurred with normal kinetics, the level of memory CTL
activity detectable in the CD40L-deficient animals 2 months following
infection was lower than that in wild-type mice. Here, we have
investigated the basis of the defect in the memory CTL response of
CD40L-deficient mice. It is shown that CD40L-deficient mice do not have
an impaired ability to maintain memory CD8+ CTL precursors
(CTLp) at stable frequencies over time but that the initial generation
of CD8+ CTLp is impaired in these animals. Further, it is
demonstrated that CD40L expression on CD8+ cells is not
required for their proliferation and differentiation into memory CTLp.
The reduction in memory CTLp generation in CD40L-deficient mice is
instead likely a consequence of defects in the CD4+ T-cell
response. These results suggest that CD40L plays a previously undefined
role in the generation of memory CD8+ CTLp following virus
infections, the nature of which is discussed.
| |
MATERIALS AND METHODS |
Mice.
Homozygous CD40L-deficient mice (70) and
wild-type controls were bred in parallel and used for experiments as
young adults (8 to 14 weeks old). A randomly selected subset of
CD40L-deficient mice was screened by PCR analysis of tail biopsy DNA to
confirm the presence of homozygous mutations in their CD40L genes.
C57BL/6 mice used as a source of peritoneal macrophages and feeder
splenocytes for the in vitro restimulation of CTLp in limiting dilution
assays were obtained either from the closed breeding colony of The
Scripps Research Institute (La Jolla, Calif.) or from Jackson
Laboratories (Bar Harbor, Maine), as were the C57BL/6 Ly5a
mice used for the creation of mixed bone marrow chimeras.
Generation of mixed bone marrow chimeras.
Bone marrow
chimeras were prepared by a method based on that described by Gao et
al. (20). Briefly, bone marrow was removed from
CD40L-deficient (Ly5b) mice and wild-type C57BL/6
Ly5a mice and was depleted of T cells by treatment with a
mixture of antibodies against Thy-1.2 (clone J1j), CD4 (clone RL172), and CD8 (clone 3.168) plus complement. Viable cells were enumerated and
mixed 1:1. Recipient mice (wild-type C57BL/6 Ly5a mice
which had been exposed to 1,000 rads of irradiation 4 to 6 h
previously) were inoculated intravenously with 2 × 106 to 3 × 106 mixed cells/mouse. The
mice were then kept for at least 8 weeks to allow time for
reconstitution to occur before they were used in experiments.
Virus growth, titration, and use for infection of mice.
All
experiments with LCMV involved the Armstrong 53b strain of the virus, a
clone triple plaque purified from ARM CA 1371 (16). Stocks
of this virus were prepared by growth on baby hamster kidney cells, and
their titers were determined by plaque assay on Vero cells as
previously described (16). Mice were infected with LCMV by
intraperitoneal (i.p.) inoculation of 2 × 105 PFU of
virus in a 200-µl volume.
Assay for LCMV-specific effector CTL activity during the primary
immune response.
LCMV-specific effector CTL activity was
quantitated by an in vitro 51Cr release assay as described
by Byrne and Oldstone (9). The effector cells were
erythrocyte-depleted splenocyte suspensions from mice infected 7 or 14 days previously with LCMV. Target cells were 51Cr-labelled
fibroblast cell lines MC57 (H-2b, i.e.,
syngeneic to the CD40L-deficient mice) and Balb Cl 7 (H-2d i.e., allogeneic to the CD40L-deficient
mice) which were either uninfected or infected 48 h prior to
51Cr labelling with LCMV at a multiplicity of infection of
3 PFU per cell. Target cells were plated at 104 per well,
and effector cells were added to give effector/target (E/T) ratios
between 100:1 and 0.5:1. All variables were tested in triplicate. The
assay time was 5 h. Results are expressed as the percentage of
specific 51Cr release, calculated as 100 × (experimental release 
spontaneous release)/(maximum
release spontaneous release).
Limiting dilution assay for quantitation of LCMV-specific CTLp
frequencies.
The assay method used was based on that described by
Nahill and Welsh (48). Briefly, thioglycolate-elicited
peritoneal macrophages from C57BL/6 mice were infected with LCMV at a
multiplicity of infection of 0.1 PFU/cell and plated at 7 × 104/well into 96-well flat-bottomed plates (Costar
Corporation, Cambridge, Mass.) in a volume of 100 µl of RPMI 1640 medium supplemented with 7% heat-inactivated fetal bovine serum, 1 mM
glutamine, 50 U of penicillin/ml, and 50 µg of streptomycin/ml
(termed RPMI 7%). After 2 days of culturing, the plates were
irradiated (2,000 rads), and half of the medium was removed from each
well and replaced with 50 µl of restimulation medium containing
105 irradiated (2,000 rads) syngeneic erythrocyte-depleted
splenocytes. The restimulation medium consisted of RPMI 1640 medium
supplemented with 5% concanavalin A (ConA)-stimulated rat spleen
supernatant, 10% heat-inactivated fetal bovine serum, 2 mM glutamine,
50 µg of gentamicin/ml, and 50 µg of streptomycin/ml. Test cell
populations (either erythrocyte-depleted splenocytes or sorted
CD8+ T cells from mice previously infected for different
lengths of time with LCMV) were diluted in restimulation medium so that
they could be added to these plates at various numbers of cells per well in 100-µl volumes. Twenty-four replicate wells were set up at
each input test cell number. The plates were incubated at 37°C in a
humidified 5% CO2 atmosphere for 7 days. On day 4 of
culture, 100 µl of medium was removed from each well and replaced
with 100 µl of fresh restimulation medium. On day 7 of culture, cells from individual wells were split twofold and assayed for cytotoxic activity on LCMV-infected and uninfected syngeneic target cells (MC57)
by a 51Cr release assay. 51Cr-labelled target
cells were added to all wells at 104/well to give a final
total volume of 200 µl/well, and 51Cr release into the
supernatant was quantitated after a 5-h incubation period. Positive
wells were defined as those whose specific 51Cr release
(calculated as described above) was greater than 10%. CTLp frequencies
were estimated from the fraction of nonresponding wells at each input
cell number per well by single-hit model Poisson distribution analysis
(14).
Induction of anti-H-Y immune responses and assay for H-Y-specific
memory CTL activity.
To induce immune responses to the male
antigen H-Y, female mice were inoculated i.p. with 2 × 106 erythrocyte-depleted splenocytes from syngeneic
wild-type male mice in a 200-µl volume of phosphate-buffered saline.
H-Y-specific memory CTL activity was assayed 4 to 6 weeks later by a
method based on that described by Di Rosa and Matzinger
(15), except that cytotoxic activity was measured in
51Cr release assays. Briefly, erythrocyte-depleted
splenocyte suspensions from individual test mice were restimulated in
vitro by culture in 24-well plates at 5 × 106
cells/well together with 2 × 106 irradiated (2,000 rads) erythrocyte-depleted splenocytes from syngeneic wild-type male
mice/well in a final volume of 2 ml/well of restimulation medium. After
3 days of culture, 1 ml of medium was removed from each well and
replaced with 1 ml of fresh restimulation medium. Cells were harvested
after 6 days of culture, and the cytotoxic activity mediated by bulk
effector populations from individual animals was measured in a
51Cr release assay with syngeneic male and female
ConA-activated blasts as target cells. The latter were prepared by
culturing erythrocyte-depleted splenocytes from male and female mice
for 3 days in 24-well plates at 2 × 106/well in a
2-ml volume/well of RPMI 7% medium containing ConA at a final
concentration of 2 µg/ml. After 51Cr labelling, the
target cells were plated into 96-well plates at 104/well,
and effector cells were added to give E/T ratios between 60:1 and
7.5:1. All variables were assayed in triplicate. 51Cr
release into the supernatant was measured after 5 h. Results are
expressed as the percentage of specific 51Cr release,
calculated as described above.
BrdU incorporation studies for the analysis of lymphocyte
turnover.
The turnover of different T-cell populations stimulated
by inoculation of mice with polyinosinic-polycytidylic acid
[poly(IC)] or infection with LCMV was assessed by administering a DNA
precursor, bromodeoxyuridine (BrdU) in the drinking water and then
examining the surface markers on BrdU-labelled cells, as previously
described (64). Mice were inoculated i.p. with 150 µg of
poly(IC) (Sigma Chemical Co., St. Louis, Mo.) in 150 µl of
phosphate-buffered saline or infected with LCMV and were given sterile
drinking water containing BrdU (Sigma Chemical Co.) at 0.8 mg/ml, which
was made fresh and changed daily. At different time points thereafter, mice were sacrificed and spleen and lymph node cell suspensions were
prepared, stained in multiple colors with antibodies directed against
different lymphocyte markers and BrdU, and examined by fluorescence-activated cell sorter (FACS) analysis as described below.
FACS analysis and sorting of lymphocyte subpopulations.
Staining of cell surface antigens for FACS analysis was performed by
conventional techniques (13). Primary antibodies used in
different experiments were fluorescein isothiocyanate-conjugated anti-CD8 (clone 53-6.7; GIBCO BRL, Gaithersburg, Md.), Cy-5-conjugated anti-CD8 (clone 53-6.7), Cy-5-conjugated anti-CD4 (clone GK1.5), biotinylated anti-CD44 (clone IM7.8.1), phycoerythrin (PE)-conjugated anti-CD40L (clone MR1; Pharmingen, San Diego, Calif.), biotinylated anti-Ly5a (clone A20), and biotinylated
anti-Ly5b (clone 104). Biotinylated primary antibodies were
detected with PE-streptavidin or RED670-streptavidin (both from GIBCO
BRL). In experiments that involved costaining for BrdU, surface
staining was performed first and then the cells were washed, fixed,
permeabilized, DNase treated, washed again, and incubated with
fluorescein isothiocyanate-conjugated anti-BrdU antibody as previously
described (64). Two- and three-color staining were analyzed
with a FACScan flow cytometer, four-color staining was analyzed with a
FACSCaliber flow cytometer, and cell sorting was performed with a
FACSVantage flow cytometer (all from Becton Dickinson & Co., Mountain
View, Calif.).
| |
RESULTS |
Impairment of the virus-specific memory CD8+ CTL
response in CD40L-deficient mice.
To clarify the roles that
CD40L-dependent signalling events play in the induction and regulation
of antiviral immune responses in vivo, we have been examining the
nature of the immune response mounted by CD40L-deficient mice following
infection with different viruses. In a previous study (6),
we demonstrated that CD40L-deficient mice infected with
arenaviruses such as LCMV mount effector CD8+ CTL
responses that are indistinguishable from those of wild-type control
animals and clear the infection with normal kinetics. However,
preliminary analysis of the memory CTL activity exhibited by bulk
splenocytes 2 months following LCMV infection indicated that this
function was impaired in CD40L-deficient mice.
To assess the defect in memory CD8+ CTL activity in
CD40L-deficient mice more quantitatively, limiting dilution analysis of the virus-specific CTLp frequencies in splenocyte populations from
CD40L-deficient and wild-type control mice infected 16 weeks previously
with LCMV was performed. As shown in Fig.
1, this analysis revealed the
LCMV-specific CTLp frequency in the CD40L-deficient mice to be
approximately fourfold lower than that in the control animals at this
time point. The difference in memory CD8+ CTLp levels in
CD40L-deficient and wild-type mice 16 weeks following infection with
LCMV could potentially be due to deficits in the generation and/or the
maintenance of virus-specific CTLp in the CD40L-deficient mice. Further
experiments were carried out to investigate which factors were
involved.
View larger version (15K):
[in this window]
[in a new window]
|
FIG. 1.
LCMV-specific CTLp frequencies in the spleens of
CD40L-deficient and wild-type control mice 16 weeks following virus
infection. LCMV-specific CTLp frequencies in splenocyte suspensions
from individual CD40L-deficient (open symbols) and wild-type mice
(closed symbols) infected 16 weeks previously with 2 × 105 PFU of LCMV i.p. were quantitated by limiting dilution
assay as described in Materials and Methods. The precursor frequencies
estimated for each control (control no. 1 to 3) and CD40L-deficient
(knockout [K/o] no. 1 to 3) mouse, the mean frequency of each group
of animals (control mean and K/o mean), and the fold difference in mean
CTLp frequencies between the two groups are shown.
|
|
Analysis of the maintenance of CD8+ CTL memory in
CD40L-deficient mice.
In normal mice, virus-specific CTLp levels
are maintained at a fairly constant level after an acute virus
infection for the life of the animal (32, 40). To determine
whether CD40L-deficient mice had an impaired ability to maintain memory
CTL, groups of CD40L-deficient and control mice were infected with LCMV
and the frequency of virus-specific CTLp in sets of three mice from
each group was measured by limiting dilution assay over time after the
acute phase of the infection. Figure 2
illustrates the mean number of LCMV-specific CTLp per 106
splenocytes in the animals tested from each group at time points from 1 to 6 months postinfection. As expected, the LCMV-specific CTLp
frequency in the control mice remained very stable over the 6-month
observation period. Importantly, the virus-specific CTLp frequency in
the CD40L-deficient mice did not decline relative to that in the
control animals with time postinfection but was consistently found to
be approximately fourfold lower than the mean frequency of the
wild-type mice at all time points tested. This result shows that
CD40L-dependent signalling is not required for the maintenance of
memory CTLp at stable frequencies over time.
View larger version (10K):
[in this window]
[in a new window]
|
FIG. 2.
Maintenance of LCMV-specific CTLp at stable frequencies
over time in CD40L-deficient and wild-type control animals. Groups of
CD40L-deficient and wild-type control mice were infected i.p. with
2 × 105 PFU of LCMV on day 0. At the indicated times
postinfection, three mice from each group were sacrificed, and the
frequency of LCMV-specific CTLp in the spleen of each animal was
quantitated by limiting dilution assay as described in Materials and
Methods. The results shown are the mean number of CTLp per
106 splenocytes of the control (closed squares) and
CD40L-deficient (open circles) animals tested at each time point.
|
|
How CTL memory is maintained is currently a subject of some debate.
Virus-specific CTLp frequencies can clearly be maintained
at stable
levels for the entire life span of a mouse in the absence
of specific
antigen (
32,
40). One theory as to how this is
achieved
(
63), based on the observation that CD44
hi
(memory phenotype) CD8
+ T cells are stimulated to divide in
an antigen nonspecific fashion
by cytokines such as type 1 IFN,
suggests that the cytokine production
which accompanies the virus
infections that an animal intermittently
contracts
throughout its life drives the division of memory CTLp
at
intervals and thus maintains them at a constant level over
time. We
thus compared the turnover of CD44
hi CD8
+ T
cells stimulated by inoculation of poly(IC) (a synthetic inducer
of
type 1 IFN) in CD40L-deficient and wild-type control mice.
A high level
of turnover of CD44
hi CD8
+ T cells was
stimulated by poly(IC) in both CD40L-deficient and
wild-type mice (data
not shown). This result is in keeping with
the data in Fig.
2 showing
that virus-specific CTLp frequencies
are stably maintained over time in
CD40L-deficient mice.
Analysis of the generation of LCMV-specific CTLp in CD40L-deficient
mice.
To compare the generation of virus-specific CTLp during the
acute phase of LCMV infection in CD40L-deficient and wild-type mice,
groups of mice of each type were infected with LCMV and limiting
dilution analysis of the LCMV-specific CTLp frequencies in two or three
individual animals from each group was performed 7 and 14 days later.
The direct effector CTL activity mediated by each test population was
also measured. Figure 3
shows the results obtained at 7 days postinfection with two
CD40L-deficient and two control mice; a second experiment in which
three mice per group were tested confirmed these. Although the direct
effector CTL activity exhibited by CD40L-deficient and control mice was indistinguishable (Fig. 3a), the LCMV-specific CTLp frequencies in the
CD40L-deficient mice were clearly lower than those in the control
animals at this time point (Fig. 3b). Very similar results (data not
shown) were also obtained at day 14, although by this time
postinfection the levels of direct CTL lysis were not as high and the
CTLp frequencies were slightly lower. The processes by which effector
and memory CTL are generated during an acute virus infection can thus
be differentiated by their dependence on CD40L-mediated signalling.
CD8+ effector CTL can be generated efficiently in the
absence of CD40L; by contrast, although there is not an absolute
requirement for CD40L in the production of CD8+ memory
CTLp, CD40L-dependent signalling is clearly involved in a pathway(s)
which influences the overall efficiency with which memory CTLp are
generated.
View larger version (11K):
[in this window]
[in a new window]
|
FIG. 3.
LCMV-specific effector CTL activity and CTLp frequencies
in splenocyte populations from CD40L-deficient and wild-type mice
infected 7 days previously with LCMV. CD40L-deficient and wild-type
mice were infected i.p. with 2 × 105 PFU of LCMV.
Seven days later, two mice from each group were sacrificed, and
splenocyte suspensions from individual CD40L-deficient animals (open
symbols and dashed lines) and wild-type controls (closed symbols and
solid lines) were assayed for both ex vivo effector CTL activity (a)
and CTLp frequency (b). (a) Percentage of specific 51Cr
release (calculated as described in Materials and Methods) mediated by
each splenocyte population from syngeneic LCMV-infected target cells
over a range of different E/T ratios. Even at the highest E/T ratios,
the specific 51Cr release from control target cells
(uninfected syngeneic targets and LCMV-infected allogeneic targets)
tested in the same assay never exceeded 20% (data not shown),
indicating that the ex vivo cytotoxic activity observed was both virus
specific and major histocompatibility complex restricted. (b) Results of a limiting dilution assay used to quantitate
the LCMV-specific CTLp frequency in each splenocyte population. The
precursor frequencies estimated for each control mouse (control no. 1 and 2) and CD40L-deficient mouse (knockout [K/o] no. 1 and 2), the
mean frequency of each group of animals (control mean and K/o mean),
and the fold difference in mean CTLp frequencies between the two groups
(fold difference) are indicated. The results shown are representative
of those obtained in two separate experiments in which a total of five
CD40L-deficient and five wild-type mice were tested.
|
|
Investigation of the role of expression of CD40L on
CD8+ versus CD4+ T cells in the generation of
virus-specific CD8+ CTLp.
A number of reports have
shown that CD40L is transiently expressed on the surface not only of
activated CD4+ T lymphocytes but also of a subpopulation of
CD8+ T lymphocytes following activation (2, 28,
39). It has been demonstrated that human CD8+ T-cell
clones which express high levels of CD40L upon activation have the
capacity to stimulate B-cell activation, growth, and differentiation (29), but whether CD40L- mediated
signalling is involved in other aspects of CD8+ T-cell
biology has not been fully investigated. The process by which memory
CD8+ CTLp are generated during an immune response is poorly
understood; transient CD8+ expression of CD40L could
hypothetically be involved. As a first step toward investigating
whether CD40L expression on CD8+ T cells may be involved in
the generation of CD8+ CTLp, we assessed the expression of
CD40L on CD8+ (and also CD4+) T cells from the
spleens and lymph nodes of mice at different times after infection with
LCMV by FACS analysis following two-color staining with antibodies
against CD40L and CD4/8. The extent and kinetics of CD40L expression on
T cells in the spleen and lymph node differed. CD40L expression was
induced on a much higher proportion of T cells in the spleen, where the
percentage of CD40L-positive CD4+ cells peaked at >10% on
day 7 postinfection. On CD8+ T cells, CD40L expression was
undetectable in the lymph node, but a low percentage of positive cells
were observed in the spleen between days 3 and 14 postinfection. It was
thus clear that CD40L expression was much more prominent on
CD4+ cells than on CD8+ cells after LCMV
infection. However, the sensitivity of the staining method used in this
experiment would not have allowed the detection of low levels of CD40L
expression; further, as CD40L is expressed only transiently by
lymphocytes following activation, this experiment did not reveal what
proportion of cells in fact expressed CD40L at some point during the
course of the infection. The possibility that low-level CD40L
expression on CD8+ cells played a role in the generation of
CD8+ CTLp thus could not be ruled out.
In a further experiment, the activation and proliferation of
CD4
+ and CD8
+ T cells over the course of LCMV
infection in CD40L-deficient
and wild-type mice were compared. Groups
of CD40L-deficient and
wild-type control animals were infected with
LCMV and immediately
given drinking water containing BrdU to label
dividing lymphocytes.
At different times following infection, two mice
from each group
were sacrificed, and the expression of CD4/8, CD44, and
BrdU by
spleen and lymph node cells was determined by three-color FACS
analysis. Similar numbers of total CD8
+ cells were found in
CD40L-deficient and control mice at all time
points (Fig.
4). Figure
5 illustrates for both CD8
+
and CD4
+ T cells the mean percentage of BrdU-positive
total, CD44
hi, and CD44
lo cells in the spleens
of the mice from each group tested at each
time point. There was
essentially no difference in the proliferation
of CD8
+ T
cells in the CD40L-deficient mice compared to that in the wild-type
mice. CD44
lo (naïve phenotype) CD8
+ T
cells were activated and began to divide by day 3 postinfection.
On day
7, more than 50% of the CD44
lo CD8
+ T cells in
the spleens of both CD40L-deficient and control mice
were BrdU
positive, and the percentage of CD44
hi CD8
+ T
cells had increased dramatically (from 13% of splenocytes on
day 1 postinfection to 54% on day 7 in the wild-type mice and
from 15% of
splenocytes on day 1 postinfection to 50% on day 7
in the
CD40L-deficient animals). By this time point, almost all
of the memory
phenotype (CD44
hi) CD8
+ T cells in the spleens
(and lymph nodes; data not shown) of both
groups of mice had also
divided. This result is in keeping with
the finding that
CD44
hi CD8
+ T-cell turnover in response to
poly(IC) was not impaired in CD40L-deficient
mice.
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 4.
Changes in the total number of CD8+ T cells
in the spleens and lymph nodes of wild-type and CD40L-deficient mice
following infection with LCMV. Wild-type and CD40L-deficient mice were
infected i.p. with 2 × 105 PFU of LCMV. At the
indicated times (days) postinfection, two mice from each group were
sacrificed, and the total number of CD8+ T cells in the
spleen and lymph nodes of each animal was determined. The results shown
are the mean total CD8+ T-cell counts of the wild-type
(closed squares and solid lines) and CD40L-deficient (open circles and
dashed lines) mice. Vertical bars indicate 1 standard deviation above
and below the mean value for each group of animals.
|
|
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 5.
Division of total, CD44hi and
CD44lo CD8+ and CD4+ splenic T
cells over time following infection of wild-type and CD40L-deficient
mice with LCMV. Groups of wild-type and CD40L-deficient mice were
infected i.p. with 2 × 105 PFU of LCMV and
immediately given drinking water containing BrdU to label dividing
lymphocytes. At the indicated times (days) postinfection, two mice from
each group were sacrificed, and the expression of CD4/8, CD44, and BrdU
by spleen cells was determined by FACS analysis. Shown (for total,
CD44hi, and CD44lo T cells of the
CD8+ and CD4+ subsets, as indicated) are the
mean percentages of BrdU-positive cells (percentage BrdU+)
in the wild-type (closed squares and solid lines) and CD40L-deficient
(open circles and dashed lines) mice tested at each time point. The
vertical bars indicate 1 standard deviation above and below the mean
value for each group of animals. Standard deviations smaller than the
size of the symbols are not apparent.
|
|
Figure
5 also illustrates that the early activation and turnover of
CD44
hi CD4
+ T cells were likewise not seriously
impaired in the CD40L-deficient
mice; more than 80% of the
CD44
hi CD4
+ T cells in the spleens of both
CD40L-deficient and wild-type
mice were BrdU positive by day 7 postinfection. However, the BrdU
labelling of naïve phenotype
CD4
+ T cells in the CD40L-deficient mice was substantially
reduced
compared to that in the wild-type control animals. Whereas an
average of 18% of the CD44
lo CD4
+ T cells in
the spleens of the wild-type mice had incorporated
BrdU by day 7 postinfection, only 7% had done so in the CD40L-deficient
animals.
This could potentially have been due to differences in
the rate of
thymic output of CD4
+ T cells in CD40L-deficient compared
to wild-type mice or could
reflect an impairment in the activation and
proliferation of naïve
CD4
+ T cells in
LCMV-infected CD40L-deficient mice. The fact that
the activation and
proliferation of naïve CD4
+ T cells in response to
LCMV infection may have been impaired
while that of naïve
CD8
+ T cells clearly was not provided further suggestive
evidence
that a defect in CD4
+ rather than CD8
+
functioning may underlie the observed defect in the generation
of
CD8
+ memory CTLp in CD40L-deficient mice.
To more conclusively determine the role of CD40L expression on
CD8
+ T cells themselves in the generation of memory CTLp,
an experiment
was designed in which the generation of LCMV-specific
memory CTLp
from CD8
+ T cells derived from CD40L-deficient
and wild-type mice could
be directly compared in the same
CD4
+ T-cell environment. Mixed bone marrow chimeras were
created by
reconstituting irradiated wild-type Ly5
a
H-2b-mice with a mixture of bone marrow derived
from CD40L-deficient
Ly5
b H-2b and
wild-type Ly5
a H-2b mice. In the
reconstituted mice, 75 to 80% of peripheral T cells
were
Ly5
a+ (i.e., able to express normal levels of CD40L). These
chimeras
were infected with LCMV, and at 7 days and 2 months
postinfection,
the frequency of LCMV-specific CTLp in sorted
populations of Ly5
a+ and Ly5
b+ CD8
+
T cells from individual chimeric mice was determined by limiting
dilution analysis. As the results in Fig.
6 show, the LCMV-specific
CTLp
frequencies in the Ly5
a+ and Ly5
b+
CD8
+ T-cell populations derived from each mouse were not
appreciably
different. This experiment thus demonstrates that memory
CD8
+ CTLp can be generated just as efficiently from
CD8
+ T cells which are unable to express CD40L as from
CD8
+ T cells derived from wild-type mice and suggests that
the efficiency
of generation of memory CD8
+ CTLp is
indirectly influenced by events triggered by CD40L-mediated
signalling
between CD4
+ T lymphocytes and other cells.
View larger version (14K):
[in this window]
[in a new window]
|
FIG. 6.
Experiment comparing the generation of LCMV-specific
memory CTLp from CD8+ T cells derived from CD40L-deficient
and wild-type mice in the same CD4+ T-cell environment.
Mixed bone marrow chimeras were created by reconstituting irradiated
wild-type Ly5a H-2b mice with a
mixture of bone marrow derived from CD40L-deficient Ly5b
H-2b and wild-type Ly5a
H-2b mice. These chimeras were infected i.p.
with 2 × 105 PFU of LCMV, and at 7 days and 2 months
postinfection, the frequency of LCMV-specific CTLp in sorted
populations of Ly5a+ (circles) and Ly5b+
(squares) CD8+ T cells from individual chimeric mice was
determined by limiting dilution assay as described in Materials and
Methods. The precursor frequencies estimated for the Ly5a+
and Ly5b+ CD8+ T cells from each mouse tested
are indicated.
|
|
Investigation of the memory CD8+ CTL response to H-Y in
CD40L-deficient mice.
Whereas the primary LCMV-specific
CD8+ CTL response is known to be CD4+ T-cell
independent (41, 45, 52), in other systems CD8+
CTL are much more dependent on help from CD4+ T cells. A
classic example of this is the CD8+ CTL response to the
male antigen H-Y (26, 58, 67). We reasoned that if, as
suggested by the above-mentioned experiments in the LCMV system, the
defect in generation of CD8+ CTLp in CD40L-deficient mice
was due to the fact that CD4+ T cells influence the
generation of CD8+ CTLp via pathway(s) that involve
CD40L-mediated signalling, then the defect in generation of memory
CD8+ CTLp in CD40L-deficient mice may be even more apparent
in the H-Y system. We thus compared the H-Y-specific memory CTL
response in CD40L-deficient and wild-type female mice immunized 4 to 6 weeks previously with splenocytes from syngeneic wild-type male mice.
As the in vitro expansion of H-Y-specific CD8+ CTLp is
known to be dependent on cytokines produced by CD4+ T cells
(15), test splenocyte populations were restimulated in vitro
in the presence of cytokine-containing supernatants so that differences
observed in their lytic activities would reflect true differences in
the input CD8+ CTLp content rather than defective expansion
of these cells in vitro. Figure 7 shows
that although H-Y-specific memory CTL responses were readily detected
in bulk CTL assays with effector cells from wild-type mice, they could
not be detected in CD40L-deficient animals. Similarly, when limiting
dilution assays were carried out, the frequency of H-Y-specific CTLp in
CD40L-deficient mice was found to be below the limit of detection of
the assay (<1 per 500,000 splenocytes). These results lend further
support to the hypothesis that CD4+ T cells play a role in
the generation of CD8+ memory CTLp.
View larger version (11K):
[in this window]
[in a new window]
|
FIG. 7.
H-Y-specific memory CTL activity in CD40L-deficient and
wild-type mice. Female CD40L-deficient and wild-type mice were
immunized i.p. with splenocytes from syngeneic wild-type male mice.
Four weeks later, two to three mice from each group were sacrificed,
and the H-Y-specific memory CTL activity mediated by in
vitro-restimulated splenocyte populations from individual animals was
determined as described in Materials and Methods. The results shown are
the mean percentage of specific 51Cr release (calculated as
described in Materials and Methods) mediated by the wild-type (closed
symbols and solid lines) and CD40L-deficient (open symbols and dashed
lines) mice from syngeneic male target cells (squares) and, as a
control, syngeneic female target cells (circles) over a range of
different E/T ratios as indicated. The results are representative of
data obtained in two independent experiments.
|
|
| |
DISCUSSION |
CD8+ CTL play a key role in control of many virus
infections, and the need for vaccines to elicit strong CD8+
T-cell responses in order to provide optimal protection in such infections is increasingly apparent. However, the mechanisms involved in the induction and maintenance of CD8+ CTL memory are
currently poorly understood. In this study, we have investigated the
involvement of CD40L-mediated interactions in these processes by
analyzing the basis of a defect we had previously observed
(6) in the memory CTL response of CD40L-deficient mice. We
show firstly that the maintenance of memory CD8+ CTLp at
stable frequencies over time is not dependent on CD40L-mediated interactions, as this is not impaired in CD40L-deficient mice. By
contrast, we demonstrate that CD40L-mediated interactions do impact
upon the generation of memory CD8+ CTLp, as these cells are
produced at lower frequencies during the primary immune response in
CD40L-deficient mice than in wild-type animals. Further, we show that
expression of CD40L by CTLp themselves is not an essential step during
their expansion and differentiation from naïve CD8+
cells into memory CTLp. The reduction in memory CTLp generation in
CD40L-deficient mice is more likely a consequence of defects in the
CD4+ T-cell response mounted by these animals.
How CD8+ CTL memory is maintained, and in particular the
question of whether persistent contact with antigen is required, is a
subject of intensive debate (1, 37, 59). Persistent contact with specific antigen appears to be required to maintain memory T cells
in a state of chronic activation which, it has been argued, may be
necessary if they are to provide protective immunity against certain
forms of viral challenge (3, 36, 37). However, several
studies have convincingly demonstrated that memory CD8+ T
cells are able to survive at constant levels over time in the complete
absence of the antigen to which they were elicited (32, 40,
47). Two theories as to how their survival may be maintained propose the involvement of stimulation with cross-reactive
environmental antigens (5, 56) or stimulation by cytokines
(such as type 1 IFNs) elicited during immune responses to unrelated
agents (63). Our data demonstrate that whatever the
mechanism involved, CD40L-mediated interactions do not play an
essential role. This observation could be accommodated by either of the
two theories above. In the latter case, it would imply that production
of the cytokines which stimulate bystander turnover of the memory
CD8+ T cells is not significantly impaired in the absence
of CD40L-mediated interactions; this would not be surprising in the
case of innate cytokines such as type 1 IFNs. Alternatively, if the
former mechanism is involved, CD40L-mediated signalling must not be
required for the memory CTLp to be efficiently stimulated by the
cross-reactive antigens. This is in contrast to the stimulation of the
generation of memory CTLp during the initial immune response to
specific antigen, which we have shown does require CD40L-mediated
signalling.
The process by which memory CD8+ CTLp are initially
generated is just as unclear as the mechanism by which CTL memory is
subsequently maintained. Demonstrating a role for CD40L-mediated
interactions in this process, we went on to investigate whether
expression of CD40L on CD8+ CTLp themselves was involved.
CD40L is transiently expressed not only on CD4+ T cells but
also on a subpopulation of CD8+ T cells following
activation (2, 28, 39); it was possible that signalling
mediated via this molecule may play a role in the differentiation of
this subset of CD8+ cells into memory CTLp. However, this
did not prove to be the case; instead, the reduction in memory CTLp
generation in CD40L-deficient mice appeared to be a consequence of
defects in the CD4+ T-cell response mounted in the absence
of CD40L-mediated interactions.
The requirement for (and nature of) CD4+ T-cell help for
CD8+ CTL responses is also not well understood. Whether
CD4+ T cells are required for primary CTL responses to be
elicited is dependent on the system studied. Thus, virus-specific
CD8+ CTL responses are efficiently induced in the absence
of CD4+ T cells following infection of mice with many
(8, 41, 42, 45, 49) but not all viruses (69), and
the ability to prime mice with CD8 epitopic sequences in the absence of
CD4 epitopes is dependent on the immunization protocol followed
(55). Further, although effector CTL responses clearly can
be elicited to many viruses without the help of CD4+ T
cells, CD8+ T-cell responses do not seem to be sustained
during persistent virus infections in the absence of CD4+ T
cells (10, 62). In both viral and nonviral systems,
CD8+ T cells are more readily deleted after a transient
response to antigen if CD4+ help is not available (4,
34, 44). The role of CD4+ T-cell help in the
generation and/or maintenance of long-term immunological memory in the
CD8+ compartment is a controversial area. Two previous
studies of the LCMV system found that memory CTL responses were
impaired in major histocompatibility complex class II-deficient and
CD4-deficient mice (12, 68). The first did not determine
whether the generation and/or the maintenance of immune memory was
affected, while the second suggested that memory CD8+ CTLp
were generated at normal levels in the absence of CD4+ T
cells but subsequently declined in frequency over time. However, the
latter result is at odds with the conclusion drawn from a less
quantitative study which suggested that LCMV-specific memory CTL
activity persisted over time in CD4-deficient mice (4) and
with findings in the H-Y system that once memory CD8+ CTL
are formed, their long-term survival does not require help from
CD4+ T cells (7, 15). Our data showing that the
generation but not the maintenance of LCMV-specific CD8+
CTLp is impaired in CD40L-deficient mice in which the CD4+
T-cell response is defective support the view that the maintenance of
CD8+ memory CTLp at stable frequencies over time does not
require help from CD4+ T cells mediated via CD40L. Further,
our results suggest a previously unappreciated role for
CD4+ T cells in the initial generation of CD8+
memory CTLp.
There are several mechanisms by which CD4+ T cells could
potentially influence the generation of memory CD8+ CTLp.
Firstly, they may mediate antiviral effects (e.g., via production of
cytokines such as IFN-) which affect the antigen load to which
CD8+ T cells are exposed during the early stages of the
infection. Exposure of CD8+ T cells to very high levels of
viral antigen in the early stages of LCMV infection has been shown to
result in complete exhaustion of the CD8+ CTL response
(46); it could thus be envisaged that if in the absence of
optimal CD4+ T-cell functioning there was a moderate
increase in the viral load, the level of generation of CD8+
CTLp may be reduced somewhat. However, two lines of evidence argue
against this being the mechanism underlying the CD4+ T-cell
dictated reduction in CD8+ CTLp generation we observed in
CD40L-deficient mice. Firstly, the titers of infectious virus and
kinetics of virus clearance in CD40L-deficient mice did not differ
appreciably from those in wild-type animals infected with the same dose
of LCMV (6). Secondly, the phenomenon of CTL exhaustion is
manifest at the level of effector CTL activity in addition to CTLp
generation, but as shown in Fig. 3, the deficit in virus-specific CTLp
generation in CD40L-deficient mice occurred independently of any
deficit in primary effector CTL activity.
An alternative, more direct mechanism by which CD4+ T cells
may influence the generation of virus-specific CD8+ memory
CTLp is via production of cytokines which stimulate T-cell proliferation and/or affect T-cell survival. The importance of cytokines in determining the fate of CD8+ T cells after
antigenic stimulation has been illustrated in the H-Y system, in which
IL-2 was shown to considerably delay the deletion of specific
CD8+ T cells activated by antigenic stimulation in the
absence of CD4+ T-cell help (34).
CD4+ T cells are the major producers of IL-2 during LCMV
infection of mice (33). In CD40L-deficient mice, in which
CD4+ T-cell activation is impaired (24, 25), the
amount of this and/or of other cytokines available to CD8+
T cells may thus be limiting. It is notable that although memory CTLp
were generated at reduced frequencies in CD40L-deficient mice, the
proliferation of CD8+ T cells was not affected (Fig. 5).
Thus, if a deficit in cytokine production by CD4+ T cells
does underlie the defect in memory CD8+ CTLp generation in
CD40L-deficient mice, the cytokine(s) involved must impact on
differentiation decisions made by CD8+ T cells rather than
just controlling their overall extent of activation and proliferation.
A third potential mechanism by which CD4+ T cells may
affect the generation of memory CD8+ CTL is by activating
and inducing the expression of costimulatory molecules upon
antigen-presenting cells. It has recently become apparent that
CD40L-CD40 interactions play a central role in the cognate interactions
between CD4+ T cells and antigen-presenting cells, which
are necessary for both cell types to become fully activated (22,
24, 71). CD40L-deficient mice have been shown to express reduced
levels of B7 in their lymphoid tissues during the immune response to an
adenoviral vector (71); other costimulatory molecules known to be induced by CD40L-mediated interactions are CD44H and ICAM-1 (27, 57). That CD4+ T cells provide help not
only for the generation of memory CTLp but also for other
CD8+ T-cell responses by inducing costimulatory activity on
antigen-presenting cells is an attractive hypothesis, as it can account
for the differences observed in the requirements for CD4+
T-cell help in different systems (examples of which were discussed above). In situations in which the costimulatory activity necessary for
a particular CD8+ T-cell response is provided by an
alternative mechanism, the response will appear to be CD4 independent.
For example, certain subtypes of influenza virus are able to induce
expression of CD86 on antigen-presenting cells, and the
CD8+ T-cell response to these influenza subtypes is
CD4+ T-cell independent, whereas CD4+ T-cell
help is required to elicit CD8+ T-cell responses to other
influenza subtypes under the same conditions (69). We favor
this mechanism as being most likely to account for the CD4+
T-cell dictated deficit in memory CD8+ CTLp generation in
CD40L-deficient mice because it could readily account for our
observation that memory CTLp generation but not effector CTL activity
is affected in the early stages of the immune response. The lineage
relationship between effector and memory CTL has long been a subject of
debate; however, it was recently shown that induction of the two can be
differentiated on the basis of their requirements for costimulation
(43). We hypothesize that the costimulatory requirements for
the effector CTL response are adequately met in LCMV-infected
CD40L-deficient mice (likely because they can be induced by
CD4+ T-cell independent mechanisms), whereas those for
memory CTLp generation are not.
In summary, our data illustrate that the generation of CD8+
CTLp is a process that can be distinguished from the production of
effector CTL by its greater dependence on CD40L. We hypothesize that
the role of CD40L (expressed on CD4+ T cells) is to
activate antigen-presenting cells to express costimulatory activity
necessary to drive the differentiation of CD8+ T cells into
memory cells. How dependent the generation of memory CTLp (and also the
effector CTL response) is on CD40L will depend on the nature and level
of costimulatory activity induced on antigen-presenting cells by other
mechanisms. These findings have important implications for the design
of antiviral vaccines, suggesting that in order to induce an optimal
memory CTL response, the vaccine should be formulated to stimulate a
good primary CD4+ T-cell response and/or should include
adjuvants which activate the expression of high levels of costimulatory
activity on antigen-presenting cells. Further, these findings suggest
that it should be possible to induce long-lived CTL responses in
situations of CD4+ T-cell deficiency (e.g., in human
immunodeficiency virus type 1-infected patients) provided that the
antigenic challenge is designed to induce suitable costimulatory
activity.
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grants AI37430 (P.B.), AG04342
(P.B. and M.B.A.O.), and AI09484 (M.B.A.O.). I.S.G. was an Associate and R.A.F. is an Investigator of the Howard Hughes Medical Institute. I.S.G. is currently a Fellow of the Juvenile Diabetes Foundation. D.F.T. was the recipient of a Centennial Fellowship from the Medical Research Council of Canada.
| |
FOOTNOTES |
*
Corresponding author. Present address: The Edward
Jenner Institute for Vaccine Research, Compton, Newbury, Berkshire RG20 7NN, United Kingdom. Phone: 1635 577913. Fax: 1635 577901. E-mail: seph.borrow{at}bbsrc.ac.uk.
| |
REFERENCES |
| 1.
|
Ahmed, R., and D. Gray.
1996.
Immunological memory and protective immunity: understanding their relation.
Science
272:54-60[Abstract].
|
| 2.
|
Armitage, R. J.,
W. C. Fanslow,
L. Strockbine,
T. A. Sato,
K. N. Clifford,
B. M. Macduff,
D. M. Anterson,
S. D. Gimpel,
T. Davis-Smith,
C. R. Malisewski,
E. A. Clark,
C. A. Smith,
K. H. Grabstein,
D. Cosman, and M. K. Spriggs.
1992.
Molecular and biological characterization of a murine ligand for CD40.
Nature
357:80-82[Medline].
|
| 3.
|
Bachmann, M. F.,
T. M. Kundig,
H. Hengartner, and R. M. Zinkernagel.
1997.
Protection against immunopathological consequences of a viral infection by activated but not resting cytotoxic T cells: T cell memory without "memory T cells"?
Proc. Natl. Acad. Sci. USA
94:640-645[Abstract/Free Full Text].
|
| 4.
|
Battegay, M.,
D. Moskophidis,
A. Rahemtulla,
H. Hengartner,
T. W. Mak, and R. M. Zinkernagel.
1994.
Enhanced establishment of a virus carrier state in adult CD4+ T-cell-deficient mice.
J. Virol.
68:4700-4704[Abstract/Free Full Text].
|
| 5.
|
Beverley, P. C. L.
1990.
Is T-cell memory maintained by crossreactive stimulation?
Immunol. Today
11:203-205[Medline].
|
| 6.
|
Borrow, P.,
A. Tishon,
S. Lee,
J. Xu,
I. S. Grewal,
M. B. A. Oldstone, and R. A. Flavell.
1996.
CD40L-deficient mice show deficits in antiviral immunity and have an impaired memory CD8+ CTL response.
J. Exp. Med.
183:2129-2142[Abstract/Free Full Text].
|
| 7.
|
Bruno, L.,
J. Kirberg, and H. Von Boehmer.
1995.
On the cellular basis of immunological T-cell memory.
Immunity
2:37-43[Medline].
|
| 8.
|
Buller, R. M.,
K. L. Holmes,
A. Hugin,
T. N. Frederickson, and I. H. Morse.
1987.
Induction of cytotoxic T-cell responses in vivo in the absence of CD4 helper cells.
Nature
328:77-79[Medline].
|
| 9.
|
Byrne, J. A., and M. B. A. Oldstone.
1984.
Biology of cloned cytotoxic T lymphocytes specific for lymphocytic choriomeningitis virus: clearance of virus in vivo.
J. Virol.
51:682-686[Abstract/Free Full Text].
|
| 10.
|
Cardin, R. D.,
J. W. Brooks,
S. R. Sarawar, and P. C. Doherty.
1996.
Progressive loss of CD8+ T cell mediated control of a -herpes virus in the absence of CD4+ T cells.
J. Exp. Med.
184:863-871[Abstract/Free Full Text].
|
| 11.
|
Cella, M.,
D. Scheidegger,
K. Palmer-Lehman,
P. Lane,
A. Lanzavecchia, and G. Alber.
1996.
Ligation of CD40 on dendritic cells triggers production of high levels of interleukin-12 and enhances T cell stimulatory capacity: T-T help via APC activation.
J. Exp. Med.
184:747-752[Abstract/Free Full Text].
|
| 12.
|
Christensen, J. P.,
O. Marker, and A. R. Thomsen.
1994.
The role of CD4+ T cells in cell-mediated immunity to LCMV: studies in MHC class I and class II deficient mice.
Scand. J. Immunol.
40:373-382[Medline].
|
| 13.
|
Coligan, J. E.,
A. M. Kruisbeek,
D. H. Margulies,
E. M. Shevach, and W. Strober (ed.).
1994.
Current protocols in immunology.
John Wiley & Sons, Inc., New York, N.Y.
|
| 14.
|
de St. Groth, S. F.
1982.
The evaluation of limiting dilution assays.
J. Immunol. Methods
49:11-23.
|
| 15.
|
Di Rosa, F., and P. Matzinger.
1996.
Long lasting CD8 T cell memory in the absence of CD4 T cells or B cells.
J. Exp. Med.
183:2153-2163[Abstract/Free Full Text].
|
| 16.
|
Dutko, F. J., and M. B. Oldstone.
1983.
Genomic and biological variation among commonly used lymphocytic choriomeningitis virus strains.
J. Gen. Virol.
64:1689-1698[Abstract/Free Full Text].
|
| 17.
|
Foy, T. M.,
F. H. Durie, and R. J. Noelle.
1994.
The expansive role of CD40 and its ligand, gp39, in immunity.
Semin. Immunol.
6:259-266[Medline].
|
| 18.
|
Foy, T. M.,
D. M. Page,
T. J. Waldschmidt,
A. Schoneveld,
J. D. Laman,
S. R. Masters,
L. Tygrett,
J. A. Ledbetter,
A. Aruffo,
E. Classen,
J. C. Xu,
R. A. Flavell,
S. Oehen,
S. M. Hedric, and R. J. Noelle.
1995.
An essential role for gp39, the ligand for CD40, in thymic selection.
J. Exp. Med.
182:1377-1388[Abstract/Free Full Text].
|
| 19.
|
Galy, A. H., and H. Spits.
1992.
CD40 is functionally expressed on human thymic epithelial cells.
J. Immunol.
149:775-782[Abstract].
|
| 20.
|
Gao, E.-K.,
D. Lo, and J. Sprent.
1990.
Strong T cell tolerance in parent into F1 bone marrow chimeras prepared with supralethal irradiation. Evidence for clonal deletion and anergy.
J. Exp. Med.
171:1101-1121[Abstract/Free Full Text].
|
| 21.
|
Gray, D.,
K. Siepmann, and G. Wohlleben.
1994.
CD40 ligation in B cell activation, isotype switching and memory development.
Semin. Immunol.
6:303-310[Medline].
|
| 22.
|
Grewal, I. S., and R. A. Flavell.
1996.
A central role of CD40 ligand in the regulation of CD4+ T-cell responses.
Immunol. Today
17:410-414[Medline].
|
| 23.
|
Grewal, I. S., and R. A. Flavell.
1996.
The role of CD40 ligand in costimulation and T-cell activation.
Immunol. Rev.
153:85-106[Medline].
|
| 24.
|
Grewal, I. S.,
H. G. Foellmer,
K. D. Grewal,
J. Xu,
F. Hardardottir,
J. L. Baron,
C. A. Janeway, and R. A. Flavell.
1996.
Requirement for CD40 ligand in costimulation induction, T cell activation, and experimental allergic encephalomyelitis.
Science
273:1864-1867[Abstract/Free Full Text].
|
| 25.
|
Grewal, I. S.,
J. Xu, and R. A. Flavell.
1995.
Impairment of antigen-specific T cell priming in mice lacking CD40 ligand.
Nature
378:617-620[Medline].
|
| 26.
|
Guerder, S., and P. Matzinger.
1992.
A fail-safe mechanism for maintaining self-tolerance.
J. Exp. Med.
176:553-564[Abstract/Free Full Text].
|
| 27.
|
Guo, Y.,
Y. Wu,
S. Shinde,
M. S. Sy,
A. Aruffo, and Y. Liu.
1996.
Identification of a costimulatory molecule rapidly induced by CD40L as CD44H.
J. Exp. Med.
184:955-961[Abstract/Free Full Text].
|
| 28.
|
Hermann, P.,
D. Blanchard,
B. de Saint-Vis,
F. Fossiez,
C. Gaillard,
B. Vanbervliet,
F. Briere,
J. Banchereau, and J.-P. Galizzi.
1993.
Expression of a 32 kD ligand for the CD40 antigen on activated human lymphocytes.
Eur. J. Immunol.
23:961-964[Medline].
|
| 29.
|
Hermann, P.,
C. Van-Kooten,
C. Gaillard,
J. Banchereau, and D. Blanchard.
1995.
CD40 ligand-positive CD8+ T cell clones allow B cell growth and differentiation.
Eur. J. Immunol.
25:2972-2977[Medline].
|
| 30.
|
Hollenbaugh, D.,
L. Grosmaire,
C. D. Kullas,
N. J. Chalupny,
R. J. Noelle,
I. Stamenkovic,
J. A. Ledbetter, and A. Aruffo.
1992.
The human T cell antigen gp39, a member of the TNF gene family, is a ligand for the CD40 receptor: expression of a soluble form of gp39 with B cell co-stimulatory activity.
EMBO J.
11:4313-4321[Medline].
|
| 31.
|
Hollenbaugh, D.,
H. D. Ochs,
R. J. Noelle,
J. A. Ledbetter, and A. Aruffo.
1994.
The role of CD40 and its ligand in the regulation of the immune response.
Immunol. Rev.
138:23-37[Medline].
|
| 32.
|
Hou, S.,
L. Hyland,
K. W. Ryan,
A. Portner, and P. C. Doherty.
1994.
Virus-specific CD8+ T-cell memory determined by clonal burst size.
Nature
369:652-654[Medline].
|
| 33.
|
Kasaian, M. T.,
K. A. Leite-Morris, and C. A. Biron.
1991.
The role of CD4+ cells in sustaining lymphocyte proliferation during lymphocytic choriomeningitis virus infection.
J. Immunol.
146:1955-1963[Abstract].
|
| 34.
|
Kirberg, J.,
L. Bruno, and H. von Boehmer.
1993.
CD4+8 help prevents rapid deletion of CD8+ cells after a transient response to antigen.
Eur. J. Immunol.
23:1963-1967[Medline].
|
| 35.
|
Koch, F.,
U. Stanzl,
P. Jennewein,
K. Janke,
C. Heufler,
E. Kampgen,
N. Romani, and G. Schuler.
1996.
High level IL-12 production by murine dendritic cells: upregulation via MHC class II and CD40 molecules and down-regulation by IL-10.
J. Exp. Med.
184:741-746[Abstract/Free Full Text].
|
| 36.
|
Kundig, T. M.,
M. F. Bachmann,
S. Oehen,
U. W. Hoffman,
J. J. L. Simard,
C. P. Kalberer,
H. Pircher,
P. S. Ohashi,
H. Hengartner, and R. M. Zinkernagel.
1996.
On the role of antigen in maintaining cytotoxic T-cell memory.
Proc. Natl. Acad. Sci. USA
93:9716-9723[Abstract/Free Full Text].
|
| 37.
|
Kundig, T. M.,
M. F. Bachmann,
P. S. Ohashi,
H. Pircher,
H. Hengartner, and R. M. Zinkernagel.
1996.
On T cell memory: arguments for antigen dependence.
Immunol. Rev.
150:63-90[Medline].
|
| 38.
|
Laman, J. D.,
E. Classen, and R. J. Noelle.
1996.
Functions of CD40 and its ligand, gp39 (CD40L).
Crit. Rev. Immunol.
16:59-108[Medline].
|
| 39.
|
Lane, P.,
A. Traunecker,
S. Hubele,
S. Inui,
A. Lanzavecchia, and D. Gray.
1992.
Activated human T cells express a ligand for the human B cell-associated antigen CD40 which participates in T cell-dependent activation of B lymphocytes.
Eur. J. Immunol.
22:2573-2578[Medline].
|
| 40.
|
Lau, L. L.,
B. D. Jamieson,
T. Somasundaram, and R. Ahmed.
1994.
Cytotoxic T-cell memory without antigen.
Nature
369:648-652[Medline].
|
| 41.
|
Leist, T. P.,
S. P. Cobbold,
H. Waldmann,
M. Aguet, and R. M. Zinkernagel.
1987.
Functional analysis of T lymphocyte subsets in antiviral host defense.
J. Immunol.
138:2278-2281[Abstract].
|
| 42.
|
Liu, Y., and A. Mullbacher.
1989.
The generation and activation of memory class I restricted cytotoxic T cell responses to influenza A virus in vivo does not require CD4+ T cells.
Immunol. Cell Biol.
67:413-420.
|
| 43.
|
Liu, Y.,
R. H. Wenger,
M. Zhao, and P. J. Nielsen.
1997.
Distinct costimulatory molecules are required for the induction of effector and memory cytotoxic T lymphocytes.
J. Exp. Med.
185:251-262[Abstract/Free Full Text].
|
| 44.
|
Matloubian, M.,
R. J. Concepcion, and R. Ahmed.
1994.
CD4+ T cells are required to sustain CD8+ cytotoxic T-cell responses during chronic viral infection.
J. Virol.
68:8056-8063[Abstract/Free Full Text].
|
| 45.
|
Moskophidis, D.,
S. P. Cobbold,
H. Waldmann, and F. Lehmann-Grube.
1987.
Mechanism of recovery from acute virus infection: treatment of lymphocytic choriomeningitis virus-infected mice with monoclonal antibodies reveals that Lyt-2+ T lymphocytes mediate clearance of virus and regulate the antiviral antibody response.
J. Virol.
61:1867-1874[Abstract/Free Full Text].
|
| 46.
|
Moskophidis, D.,
F. Lechner,
H. Pircher, and R. M. Zinkernagel.
1993.
Virus persistence in acutely infected immunocompetent mice by exhaustion of antiviral cytotoxic effector T cells.
Nature
362:758-761[Medline].
|
| 47.
|
Mullbacher, A.
1994.
The long-term maintenance of cytotoxic T cell memory does not require persistence of antigen.
J. Exp. Med.
179:317-321[Abstract/Free Full Text].
|
| 48.
|
Nahill, S. R., and R. M. Welsh.
1993.
High frequency of cross-reactive cytotoxic T lymphocytes elicited during the virus-induced polyclonal cytotoxic T lymphocyte response.
J. Exp. Med.
177:317-327[Abstract/Free Full Text].
|
| 49.
|
Nash, A. A.,
A. Jayasuriya,
J. Phelan,
S. P. Cobbold,
H. Waldmann, and T. Prospero.
1987.
Different roles for L3T4+ and Lyt2+ T cell subsets in the control of an acute herpes simplex virus infection of the skin and nervous system.
J. Gen. Virol.
68:825-833[Abstract/Free Full Text].
|
| 50.
|
Noelle, R. J.
1996.
CD40 and its ligand in host defence.
Immunity
4:415-419[Medline].
|
| 51.
|
Noelle, R. J.,
M. Roy,
D. M. Shephard,
I. Stamenkovic,
J. A. Ledbetter, and A. Aruffo.
1992.
A novel ligand on activated T helper cells binds CD40 and transduces the signal for the cognate activation of B cells.
Proc. Natl. Acad. Sci. USA
89:6550-6554[Abstract/Free Full Text].
|
| 52.
|
Rahemtulla, A.,
W. P. Fung-Leung,
M. W. Schilham,
T. M. Kundig,
S. R. Sambhara,
A. Narendran,
A. Arabian,
A. Wakeham,
C. J. Paige,
R. M. Zinkernagel,
R. G. Miller, and T. W. Mak.
1991.
Normal development and function of CD8+ cells but markedly decreased helper cell activity in mice lacking CD4.
Nature
353:180-184[Medline].
|
| 53.
|
Roy, M.,
T. Waldschmidt,
A. Aruffo,
J. A. Ledbetter, and R. J. Noelle.
1993.
The regulation of the expression of gp39, the CD40 ligand, on normal and cloned CD4+ T cells.
J. Immunol.
151:2497-2510[Abstract].
|
| 54.
|
Sad, S.,
L. Krishnan,
R. C. Bleackley,
D. Kagi,
H. Hengartner, and T. R. Mosmann.
1997.
Cytotoxicity and weak CD40L expression of CD8(=) type 2 cytotoxic T cells restricts their potential B cell helper activity.
Eur. J. Immunol.
27:914-922[Medline].
|
| 55.
|
Sauzet, J.-P.,
H. Gras-Masse,
J.-G. Guillet, and E. Gomard.
1996.
Influence of strong CD4 epitope on long-term virus-specific cytotoxic T cell responses induced in vivo with peptides.
Int. Immunol.
8:457-465[Abstract/Free Full Text].
|
| 56.
|
Selin, L. K.,
S. R. Nahill, and R. M. Welsh.
1994.
Cross-reactivities in memory cytotoxic T lymphocyte recognition of heterologous viruses.
J. Exp. Med.
179:1933-1943[Abstract/Free Full Text].
|
| 57.
|
Shinde, S.,
Y. Wu,
Y. Guo,
Q. T. Niu,
J. C. Xu,
I. S. Grewal,
R. A. Flavell, and Y. Liu.
1996.
CD40L is important for induction of, but not response to, costimulatory activity ICAM-1 as the 2nd costimulatory molecule rapidly up-regulated by CD40L.
J. Immunol.
157:2764-2768[Abstract].
|
| 58.
|
Simpson, E., and R. D. Gordon.
1977.
Responsiveness to hy antigen Ir gene complementation and target cell specificity.
Immunol. Rev.
35:59-75[Medline].
|
| 59.
|
Sprent, J.
1997.
Immunological memory.
Curr. Opin. Immunol.
9:371-379[Medline].
|
| 60.
|
Stamenkovic, I.,
E. A. Clark, and B. Seed.
1989.
A B-lymphocyte activation molecule related to the nerve growth factor receptor and induced by cytokines in carcinomas.
EMBO J.
8:1403-1410[Medline].
|
| 61.
|
Stout, R., and J. Suttles.
1996.
The many roles of CD40:CD40L interactions in cell-mediated inflammatory immune responses.
Immunol. Today
17:487-492[Medline].
|
| 62.
|
Thomsen, A. R.,
J. Johansen,
O. Marker, and J. P. Christensen.
1996.
Exhaustion of CTL memory and recrudescence of viremia in lymphocytic choriomeningitis virus-infected MHC class II-deficient mice and B cell deficient mice.
J. Immunol.
157:3074-3080[Abstract].
|
| 63.
|
Tough, D. F.,
P. Borrow, and J. Sprent.
1996.
Intense bystander proliferation of T cells in vivo induced by viruses and type I interferon.
Science
272:1947-1950[Abstract].
|
| 64.
|
Tough, D. F., and J. Sprent.
1994.
Turnover of naive- and memory-phenotype T cells.
J. Exp. Med.
179:1127-1135[Abstract/Free Full Text].
|
| 65.
|
van Essen, D.,
H. Kikutani, and D. Gray.
1995.
CD40 ligand-transduced co-stimulation of T cells in the development of helper function.
Nature
378:620-623[Medline].
|
| 66.
|
van Kooten, C., and J. Banchereau.
1996.
CD40-CD40 ligand: a multifunctional receptor-ligand pair.
Adv. Immunol.
61:1-77[Medline].
|
| 67.
|
von Boehmer, H.,
W. Haas, and N. K. Jerne.
1978.
Major histocompatibility complex-linked immune-responsiveness is acquired by lymphocytes differentiating in the thymus of high-responder mice.
Proc. Natl. Acad. Sci. USA
75:2439-2442[Abstract/Free Full Text].
|
| 68.
|
von Herrath, M. G.,
M. Yokoyama,
J. Dockter,
M. B. A. Oldstone, and J. L. Whitton.
1996.
CD4-deficient mice have reduced levels of memory cytotoxic T lymphocytes after immunization and show diminished resistance to subsequent virus challenge.
J. Virol.
70:1072-1079[Abstract].
|
| 69.
|
Wu, Y., and Y. Liu.
1994.
Viral induction of co-stimulatory activity on antigen-presenting cells bypasses the need for CD4+ T-cell help in CD8+ T-cell responses.
Curr. Biol.
4:499-505[Medline].
|
| 70.
|
Xu, J.,
T. M. Foy,
J. D. Lamar,
E. A. Elliott,
J. J. Dunn,
T. J. Waldschmidt,
J. Elsemore,
R. J. Noelle, and R. A. Flavell.
1994.
Mice deficient for the CD40 ligand.
Immunity
1:423-431[Medline].
|
| 71.
|
Yang, Y., and J. M. Wilson.
1996.
CD40 ligand-dependent T cell activation: requirement of B7-CD28 signalling through CD40.
Science
273:1862-1864[Abstract/Free Full Text].
|
Journal of Virology, September 1998, p. 7440-7449, Vol. 72, No. 9
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Ryu, S. J., Jung, K. M., Yoo, H. S., Kim, T. W., Kim, S., Chang, J., Choi, E. Y.
(2009). Cognate CD4 help is essential for the reactivation and expansion of CD8 memory T cells directed against the hematopoietic cell-specific dominant minor histocompatibility antigen, H60. Blood
113: 4273-4280
[Abstract]
[Full Text]
-
Hernandez, M. G. H., Shen, L., Rock, K. L.
(2008). CD40 on APCs Is Needed for Optimal Programming, Maintenance, and Recall of CD8+ T Cell Memory Even in the Absence of CD4+ T Cell Help. J. Immunol.
180: 4382-4390
[Abstract]
[Full Text]
-
Elzey, B. D., Schmidt, N. W., Crist, S. A., Kresowik, T. P., Harty, J. T., Nieswandt, B., Ratliff, T. L.
(2008). Platelet-derived CD154 enables T-cell priming and protection against Listeria monocytogenes challenge. Blood
111: 3684-3691
[Abstract]
[Full Text]
-
Sitati, E., McCandless, E. E., Klein, R. S., Diamond, M. S.
(2007). CD40-CD40 Ligand Interactions Promote Trafficking of CD8+ T Cells into the Brain and Protection against West Nile Virus Encephalitis. J. Virol.
81: 9801-9811
[Abstract]
[Full Text]
-
Summers-deLuca, L. E., McCarthy, D. D., Cosovic, B., Ward, L. A., Lo, C. C., Scheu, S., Pfeffer, K., Gommerman, J. L.
(2007). Expression of lymphotoxin-{alpha}{beta} on antigen-specific T cells is required for DC function. JEM
204: 1071-1081
[Abstract]
[Full Text]
-
Hernandez, M. G. H., Shen, L., Rock, K. L.
(2007). CD40-CD40 Ligand Interaction between Dendritic Cells and CD8+ T Cells Is Needed to Stimulate Maximal T Cell Responses in the Absence of CD4+ T Cell Help. J. Immunol.
178: 2844-2852
[Abstract]
[Full Text]
-
Fang, M., Sigal, L. J.
(2005). Antibodies and CD8+ T Cells Are Complementary and Essential for Natural Resistance to a Highly Lethal Cytopathic Virus. J. Immunol.
175: 6829-6836
[Abstract]
[Full Text]
-
Thimme, R., Appay, V., Koschella, M., Panther, E., Roth, E., Hislop, A. D., Rickinson, A. B., Rowland-Jones, S. L., Blum, H. E., Pircher, H.
(2005). Increased Expression of the NK Cell Receptor KLRG1 by Virus-Specific CD8 T Cells during Persistent Antigen Stimulation. J. Virol.
79: 12112-12116
[Abstract]
[Full Text]
-
Wodarz, D., Thomsen, A. R.
(2005). Effect of the CTL proliferation program on virus dynamics. Int Immunol
17: 1269-1276
[Abstract]
[Full Text]
-
Elrefaei, M., McElroy, M. D., Preas, C. P., Hoh, R., Deeks, S., Martin, J., Cao, H.
(2004). Central Memory CD4+ T Cell Responses in Chronic HIV Infection Are Not Restored by Antiretroviral Therapy. J. Immunol.
173: 2184-2189
[Abstract]
[Full Text]
-
Xu, M., Lepisto, A. J., Hendricks, R. L.
(2004). CD154 Signaling Regulates the Th1 Response to Herpes Simplex Virus-1 and Inflammation in Infected Corneas. J. Immunol.
173: 1232-1239
[Abstract]
[Full Text]
-
Yu, Q., Kovacs, C., Yue, F. Y., Ostrowski, M. A.
(2004). The Role of the p38 Mitogen-Activated Protein Kinase, Extracellular Signal-Regulated Kinase, and Phosphoinositide-3-OH Kinase Signal Transduction Pathways in CD40 Ligand-Induced Dendritic Cell Activation and Expansion of Virus-Specific CD8+ T Cell Memory Responses . J. Immunol.
172: 6047-6056
[Abstract]
[Full Text]
-
Lee, B. O., Hartson, L., Randall, T. D.
(2003). CD40-deficient, Influenza-specific CD8 Memory T Cells Develop and Function Normally in a CD40-sufficient Environment. JEM
198: 1759-1764
[Abstract]
[Full Text]
-
Howard, L. M., Neville, K. L., Haynes, L. M., Dal Canto, M. C., Miller, S. D.
(2003). CD154 Blockade Results in Transient Reduction in Theiler's Murine Encephalomyelitis Virus-Induced Demyelinating Disease. J. Virol.
77: 2247-2250
[Abstract]
[Full Text]
-
Hu, H.-M., Winter, H., Ma, J., Croft, M., Urba, W. J., Fox, B. A.
(2002). CD28, TNF Receptor, and IL-12 Are Critical for CD4-Independent Cross-Priming of Therapeutic Antitumor CD8+ T Cells. J. Immunol.
169: 4897-4904
[Abstract]
[Full Text]
-
Zhai, Y., Meng, L., Gao, F., Busuttil, R. W., Kupiec-Weglinski, J. W.
(2002). Allograft Rejection by Primed/Memory CD8+ T Cells Is CD154 Blockade Resistant: Therapeutic Implications for Sensitized Transplant Recipients. J. Immunol.
169: 4667-4673
[Abstract]
[Full Text]
-
Laderach, D., Movassagh, M., Johnson, A., Mittler, R. S., Galy, A.
(2002). 4-1BB co-stimulation enhances human CD8+ T cell priming by augmenting the proliferation and survival of effector CD8+ T cells. Int Immunol
14: 1155-1167
[Abstract]
[Full Text]
-
Larkin, R., Benjamin, C. D., Hsu, Y.-M., Li, Q., Zukowski, L., Silver, R. F.
(2002). CD40 Ligand (CD154) Does Not Contribute to Lymphocyte-Mediated Inhibition of Virulent Mycobacterium tuberculosis within Human Monocytes. Infect. Immun.
70: 4716-4720
[Abstract]
[Full Text]
-
Murakami, M., Sakamoto, A., Bender, J., Kappler, J., Marrack, P.
(2002). CD25+CD4+ T cells contribute to the control of memory CD8+ T cells. Proc. Natl. Acad. Sci. USA
99: 8832-8837
[Abstract]
[Full Text]
-
Serbina, N. V., Lazarevic, V., Flynn, J. L.
(2001). CD4+ T Cells Are Required for the Development of Cytotoxic CD8+ T Cells During Mycobacterium tuberculosis Infection. J. Immunol.
167: 6991-7000
[Abstract]
[Full Text]
-
Lieberman, J., Shankar, P., Manjunath, N., Andersson, J.
(2001). Dressed to kill? A review of why antiviral CD8 T lymphocytes fail to prevent progressive immunodeficiency in HIV-1 infection. Blood
98: 1667-1677
[Abstract]
[Full Text]
-
Ito, H., Kurtz, J., Shaffer, J., Sykes, M.
(2001). CD4 T Cell-Mediated Alloresistance to Fully MHC-Mismatched Allogeneic Bone Marrow Engraftment Is Dependent on CD40-CD40 Ligand Interactions, and Lasting T Cell Tolerance Is Induced by Bone Marrow Transplantation with Initial Blockade of this Pathway. J. Immunol.
166: 2970-2981
[Abstract]
[Full Text]
-
Masopust, D., Jiang, J., Shen, H., Lefrancois, L.
(2001). Direct Analysis of the Dynamics of the Intestinal Mucosa CD8 T Cell Response to Systemic Virus Infection. J. Immunol.
166: 2348-2356
[Abstract]
[Full Text]
-
Bartholdy, C., Christensen, J. P., Wodarz, D., Thomsen, A. R.
(2000). Persistent Virus Infection despite Chronic Cytotoxic T-Lymphocyte Activation in Gamma Interferon-Deficient Mice Infected with Lymphocytic Choriomeningitis Virus. J. Virol.
74: 10304-10311
[Abstract]
[Full Text]
-
Wodarz, D., May, R. M., Nowak, M. A.
(2000). The role of antigen-independent persistence of memory cytotoxic T lymphocytes. Int Immunol
12: 467-477
[Abstract]
[Full Text]
-
Andreasen, S. O., Christensen, J. E., Marker, O., Thomsen, A. R.
(2000). Role of CD40 Ligand and CD28 in Induction and Maintenance of Antiviral CD8+ Effector T Cell Responses. J. Immunol.
164: 3689-3697
[Abstract]
[Full Text]
-
Lifson, J. D., Rossio, J. L., Arnaout, R., Li, L., Parks, T. L., Schneider, D. K., Kiser, R. F., Coalter, V. J., Walsh, G., Imming, R. J., Fisher, B., Flynn, B. M., Bischofberger, N., Piatak, M. Jr., Hirsch, V. M., Nowak, M. A., Wodarz, D.
(2000). Containment of Simian Immunodeficiency Virus Infection: Cellular Immune Responses and Protection from Rechallenge following Transient Postinoculation Antiretroviral Treatment. J. Virol.
74: 2584-2593
[Abstract]
[Full Text]
-
Servet-Delprat, C., Vidalain, P.-O., Bausinger, H., Manie, S., Le Deist, F., Azocar, O., Hanau, D., Fischer, A., Rabourdin-Combe, C.
(2000). Measles Virus Induces Abnormal Differentiation of CD40 Ligand-Activated Human Dendritic Cells. J. Immunol.
164: 1753-1760
[Abstract]
[Full Text]
-
Green, E. A., Wong, F. S., Eshima, K., Mora, C., Flavell, R. A.
(2000). Neonatal Tumor Necrosis Factor {alpha} Promotes Diabetes in Nonobese Diabetic Mice by Cd154-Independent Antigen Presentation to Cd8+ T Cells. JEM
191: 225-238
[Abstract]
[Full Text]
-
Lefrancois, L., Altman, J. D., Williams, K., Olson, S.
(2000). Soluble Antigen and CD40 Triggering Are Sufficient to Induce Primary and Memory Cytotoxic T Cells. J. Immunol.
164: 725-732
[Abstract]
[Full Text]
-
McAdam, A. J., Farkash, E. A., Gewurz, B. E., Sharpe, A. H.
(2000). B7 Costimulation Is Critical for Antibody Class Switching and CD8+ Cytotoxic T-Lymphocyte Generation in the Host Response to Vesicular Stomatitis Virus. J. Virol.
74: 203-208
[Abstract]
[Full Text]
-
Iwakoshi, N. N., Mordes, J. P., Markees, T. G., Phillips, N. E., Rossini, A. A., Greiner, D. L.
(2000). Treatment of Allograft Recipients with Donor-Specific Transfusion and Anti-CD154 Antibody Leads to Deletion of Alloreactive CD8+ T Cells and Prolonged Graft Survival in a CTLA4-Dependent Manner. J. Immunol.
164: 512-521
[Abstract]
[Full Text]
-
Wodarz, D., Nowak, M. A.
(1999). Specific therapy regimes could lead to long-term immunological control of HIV. Proc. Natl. Acad. Sci. USA
96: 14464-14469
[Abstract]
[Full Text]
-
Brooks, J. W., Hamilton-Easton, A. M., Christensen, J. P., Cardin, R. D., Hardy, C. L., Doherty, P. C.
(1999). Requirement for CD40 Ligand, CD4+ T Cells, and B Cells in an Infectious Mononucleosis-Like Syndrome. J. Virol.
73: 9650-9654
[Abstract]
[Full Text]
-
Lefrancois, L., Olson, S., Masopust, D.
(1999). A Critical Role for Cd40-Cd40 Ligand Interactions in Amplification of the Mucosal Cd8 T Cell Response. JEM
190: 1275-1284
[Abstract]
[Full Text]
-
Allison Green, E., Flavell, R. A.
(1999). TRANCE-RANK, a New Signal Pathway Involved in Lymphocyte Development and T Cell Activation. JEM
189: 1017-1020
[Full Text]
Top
Abstract
Introduction
