Download Autoimmune Uveitis Control Induction of Experimental Immune

This information is current as
of June 18, 2017.
Fas and Fas Ligand Expressed on Cells of the
Immune System, not on the Target Tissue,
Control Induction of Experimental
Autoimmune Uveitis
Jennifer L. Wahlsten, Heather L. Gitchell, Chi-Chao Chan,
Barbara Wiggert and Rachel R. Caspi
J Immunol 2000; 165:5480-5486; ;
doi: 10.4049/jimmunol.165.10.5480
http://www.jimmunol.org/content/165/10/5480
Subscription
Permissions
Email Alerts
This article cites 33 articles, 17 of which you can access for free at:
http://www.jimmunol.org/content/165/10/5480.full#ref-list-1
Information about subscribing to The Journal of Immunology is online at:
http://jimmunol.org/subscription
Submit copyright permission requests at:
http://www.aai.org/About/Publications/JI/copyright.html
Receive free email-alerts when new articles cite this article. Sign up at:
http://jimmunol.org/alerts
The Journal of Immunology is published twice each month by
The American Association of Immunologists, Inc.,
1451 Rockville Pike, Suite 650, Rockville, MD 20852
Copyright © 2000 by The American Association of
Immunologists All rights reserved.
Print ISSN: 0022-1767 Online ISSN: 1550-6606.
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
References
Fas and Fas Ligand Expressed on Cells of the Immune System,
not on the Target Tissue, Control Induction of Experimental
Autoimmune Uveitis
Jennifer L. Wahlsten,* Heather L. Gitchell,* Chi-Chao Chan,* Barbara Wiggert,† and
Rachel R. Caspi1*
E
xperimental autoimmune uveitis (uveoretinitis) (EAU)2 is
an organ-specific, T cell-mediated autoimmune disease
that can be induced in rodents by active immunization
with retinal Ags or their fragments, or by adoptive transfer of
retinal-specific, syngeneic CD4⫹ T cells. EAU manifests itself as
a destructive inflammation of the neural retina and related tissues
(1– 4). The pathology of EAU in the mouse model closely resembles human uveitic diseases of putative autoimmune origin and
serves as a model for these blinding ocular inflammations (4). In
addition, because of shared basic immunopathogenic mechanisms,
elucidation of the mechanisms affecting EAU can also shed light
on the mechanisms involved in other tissue-specific autoimmune
disease models mediated by T cells.
Fas (CD95) and its ligand, FasL (CD95L), are transmembrane
proteins belonging to the TNF/nerve growth factor receptor and
TNF protein families, respectively (5). Fas and FasL interaction is
important for maintaining normal peripheral lymphocyte homeostasis during an immune response (5), in which cellular signaling through Fas elicits activation-induced cell death (6). Fas and
FasL are expressed on various tissues as well as on cells of the
*Laboratory of Immunology and †Laboratory of Retinal Cell and Molecular Biology,
National Eye Institute, National Institutes of Health, Bethesda, MD 20892
Received for publication February 1, 2000. Accepted for publication August 10, 2000.
The costs of publication of this article were defrayed in part by the payment of page
charges. This article must therefore be hereby marked advertisement in accordance
with 18 U.S.C. Section 1734 solely to indicate this fact.
1
Address correspondence and reprint requests to Dr. Rachel R. Caspi, Laboratory of
Immunology, National Eye Institute, National Institutes of Health, 10 Center Drive,
10/10N222, Bethesda, MD 20892-1957. E-mail address: [email protected]
Abbreviations used in this paper: EAU, experimental autoimmune uveitis; ␣-MMP,
␣-methyl-D-mannopyranoside; BM, bone marrow; DTH, delayed-type hypersensitivity; EAE, experimental autoimmune encephalomyelitis; FasL, Fas ligand; IRBP, interphotoreceptor retinoid-binding protein; PTX, pertussis toxin; WT, wild type.
2
Copyright © 2000 by The American Association of Immunologists
immune system, including T cells (5). In mice and in humans,
FasL is expressed on ocular tissues, and is thought to contribute to
the immunologically privileged status of the eye by causing apoptosis of invading Fas-positive leukocytes (7, 8). Interestingly,
both in mice and in humans, ocular tissues express Fas as well, and
its expression is increased in ocular inflammatory conditions (7–9
and Chan and Tarrant, unpublished). Expression of Fas in the eye
raises the possibility that it may have a role in tissue damage by
promoting apoptotic death of ocular cells.
Mice homozygous for the mutant genes lpr (lymphoproliferation) or gld (generalized lymphoproliferation disease) do not express functional Fas or FasL (10, 11), respectively, and develop
progressive autoimmune symptoms (12). Thus, lack of these molecules precipitates a spontaneous autoimmune process. However,
previous studies evaluating the susceptibility of gld and lpr mice to
induction of experimental autoimmune encephalomyelitis (EAE),
which shares essential cellular mechanisms with EAU, demonstrated a marked resistance of the gld and lpr mice to the development of clinical EAE compared with wild-type (WT) B6 mice
and pointed out the need for FasL on the infiltrating cells and of
Fas on cells of the CNS (13–15) .
In the present study, we sought to evaluate whether lack of Fas
or FasL alters the susceptibility of gld and lpr mice on the
C57BL/6 (B6) background to EAU induced by immunization with
the interphotoreceptor retinoid-binding protein (IRBP). Our results
showed that IRBP-immunized B6.gld as well as B6.lpr mice have
a diminished capacity to develop EAU. Experiments using bone
marrow (BM) chimeras, in which WT, gld, or lpr mice served
alternatively as BM donor or as recipient, led to the conclusion that
normal expression of Fas and FasL on cells of the immune system
is required for induction of EAU, but presence of Fas or FasL on
ocular tissue does not affect EAU induction. Furthermore, lpr and
0022-1767/00/$02.00
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
The Fas-Fas ligand (FasL) interaction is important for maintaining lymphocyte homeostasis by signaling for activation-induced
cell death. Mice homozygous for the lpr or gld mutations do not express functional Fas or FasL, respectively, and spontaneously
develop progressive autoimmune symptoms. Recent studies implicated expression of FasL on immunologically privileged tissues
in protection from immune-mediated damage. Conversely, tissue expression of Fas may facilitate damage. We evaluated the
susceptibility of lpr and gld mice to induction of experimental autoimmune uveitis (EAU), a T cell-mediated autoimmune disease
induced with retinal Ags, which targets the neural retina. gld as well as lpr mice immunized with a retinal Ag developed disease
of lower incidence and severity than wild-type controls. Delayed hypersensitivity responses were not significantly different among
immunized gld, lpr, or wild-type mice, although in vitro Ag-specific lymphocyte responses of the mutant mice were lower. To
evaluate whether the diminished ability of gld and lpr mice to develop EAU was due to a defect at the level of the tissue or the
immune system, radiation bone marrow chimeras constructed between wild-type and mutant mice were immunized to induce
EAU. Mutant recipients of wild-type bone marrow, but not wild-type recipients of mutant bone marrow, developed normal disease
scores. These results indicate that normal expression of Fas and of FasL on cells of the immune system is important for EAU
expression. Unexpectedly, neither lack of Fas nor lack of FasL on the ocular tissues affected expression of EAU. The Journal of
Immunology, 2000, 165: 5480 –5486.
The Journal of Immunology
gld mice appeared to mount a Th1-low response to the IRBP Ag.
Although our data superficially agree with reports on reduced susceptibility of these mice to EAE (13–15), the underlying mechanisms appear to differ.
Materials and Methods
Animals
C57BL/6 WT mice (B6), C57BL/6 mice congenic for CD45.1 (CD45.1),
and C57BL/6 mice homozygous for gld or lpr defects (gld or lpr, respectively) were either purchased from The Jackson Laboratory (Bar Harbor,
ME) or were bred on site from breeding pairs kindly supplied by Tom
Ferguson (Washington University, St. Louis, MO). All animals were
housed under specific pathogen-free conditions, were given water and
chow ad libitum, and were used at 2– 6 mo of age. Mutant mice with
obvious splenomegaly or in poor physical condition were excluded from
the study. Ages of the mice used in the different experiments are specified
in the corresponding figure legends. WT mice between 2 and 6 mo of age
show no discernible changes in susceptibility to disease or in immunological responses. Use of the animals conformed to institutional and National
Institutes of Health guidelines.
Reagents
Induction and scoring of EAU
By immunization. WT C57BL/6 mice were immunized s.c. in the
thighs and base of tail with 125 ␮g IRBP in 0.2 ml emulsion 1:1 v/v with
CFA containing 2.5 mg/ml M. tuberculosis, and were simultaneously injected i.p. with 1 ␮g PTX in 0.1 ml as an additional adjuvant. gld or lpr
mice were immunized with either the same dose or with 200 ␮g IRBP and
2 ␮g PTX in the same volume of CFA.
By adoptive transfer. Donors immunized as above with 125 ␮g IRBP
were sacrificed 14 days after immunization, and their pooled lymph node
and spleen cells were restimulated for 72 h in culture with 30 ␮g/ml IRBP
before injecting 40 ⫻ 106 cells i.p. into recipients.
Eyes were collected 21 days after immunization, or 10 days after adoptive transfer, within 5 min of euthanasia. The eyes were prefixed for 1 h in
4% phosphate-buffered glutaraldehyde and then were transferred into 10%
phosphate-buffered formaldehyde until processing. Fixed and dehydrated
tissue was embedded in methacrylate, and 4–6-␮m sections were cut
through the pupillary-optic nerve plane. Sections were stained by hematoxylin and eosin. An ocular pathologist evaluated the presence and grade
of disease in a masked fashion after examining six sections cut at different
levels for each eye. Severity of EAU for each eye was scored on a scale of
0 (no disease) to 4 (maximum disease) in half-point increments, according
to a described semiquantitative system (17). Briefly, the minimal criterion
to score an eye as positive by histopathology was inflammatory cell infiltration of the anterior chamber, ciliary body, choroid, vitreous, or retina
(EAU grade 0.5). Progressively higher grades were assigned for presence
of discrete lesions in the tissue, such as vasculitis, granuloma formation,
retinal folding and/or detachment, photoreceptor damage, etc. The grading
system takes into account lesion type, size, and number.
Delayed-type hypersensitivity (DTH)
Two days before the termination of an experiment, mice received 10 ␮g of
IRBP in 10 ␮l intradermally into the pinna of one ear. The other ear was
injected similarly, but with PBS. Ear swelling was measured at the termination of the experiment 48 h later with a spring-loaded micrometer. DTH
results are expressed as Ag-specific swelling, calculated as the difference in
microns between thickness of the IRBP-injected ear and the
PBS-injected ears.
Lymphocyte proliferation
Draining lymph nodes (inguinals and iliacs) were collected at the termination of an experiment and pooled within each group. Triplicate cultures
of 5 ⫻ 105 cells/0.2 ml/well were stimulated with 30 ␮g/ml IRBP in 96well flat-bottom plates in RPMI 1640 containing 1% naive mouse serum
and 20 mg/ml ␣-MMP (to neutralize possible traces of Con A, which is
used during the purification of IRBP). The cultures were incubated for 48 h
and were pulsed with [3H]thymidine (1 ␮Ci/10 ␮l/well) for the last 18 h.
The data are presented as the average difference in cpm between triplicate
cultures of IRBP-stimulated and unstimulated lymph node or splenocyte
cells ⫾ SD from a representative experiment.
Determination of lymphokine content in culture supernatants by
ELISA
Spleens were removed at the termination of an experiment and pooled
within each group. The cells were cultured in 24-well flat-bottom plates
(5 ⫻ 106 cells/ml/well) with 30 ␮g/ml of IRBP in RPMI 1640 medium
containing 1% fresh-frozen syngeneic mouse serum and 20 mg/ml
␣-MMP. Supernatants were collected for cytokine production analysis after
48 h. IFN-␥, IL-4, and IL-5 were measured by ELISA using paired Ab
minikits from Endogen. IL-10 was measured using an ELISA kit from
Endogen.
BM chimeras
Recipient mice were exposed to two doses of 550 rads, given 8 h apart, in
a Gammacell irradiator utilizing a 137Cs source 24 h before BM transplantation. Syngeneic BM cells were obtained by flushing freshly dissected
femurs of donor mice and tibias with RPMI 1640 through a 23-gauge
needle. The cells were teased into a single-cell suspension, and 75 ⫻ 106
viable cells in 0.2 ml of RPMI 1640 supplemented with 1% normal mouse
serum were injected i.v. into irradiated recipients. Extent of chimerism in
recipient mice 2 mo after reconstitution was determined by flow cytometry
when using CD45.1 congenic mice on a C57BL/6 background as donors or
as recipients, and ranged between 88 and 98%. Between 1 and 2 ⫻ 106
splenocytes were stained for two-color analyses with 1 ␮g of FITC-conjugated anti-CD4 (clone RM4-4) and 1 ␮g of either PE-conjugated antiCD45.1 (clone A20) or PE anti-CD45.2 (clone 104) in the presence of 2 ␮g
of anti-CD16 (Fc block). A total of 3 ⫻ 105 total events was collected and
analyzed using a Becton Dickinson FACScalibur and CellQuest analysis
software (San Jose, CA).
Reproducibility and statistical analysis
Experiments were repeated at least twice. Statistical analysis of EAU
scores was done according to the test of Snedecor and Cochran (18) for
linear trend in proportions (nonparametric, frequency based). Each mouse
(average of both eyes) was treated as one statistical event. Delayed hypersensitivity scores were analyzed using an independent t test. Probability
values of p ⬍ 0.05 were considered to be significant.
Results
gld and lpr mice are less susceptible to induction of EAU by
immunization
To determine whether functional Fas or FasL expression is necessary for active EAU induction, we immunized B6 mice with 100
␮g IRBP and gld or lpr mice with 100 ␮g or 200 ␮g IRBP as
described in Materials and Methods. In six separate experiments
comparing gld or lpr mice with WT controls (three each combined
for gld and lpr), gld and lpr mice developed EAU with a greatly
reduced incidence and severity (Fig. 1A). Resistance to EAU induction in the mutants was maintained even when the IRBP and
PTX doses were doubled. These data show that functional expression of Fas and FasL is required for full induction of EAU.
Immunological responses of IRBP-immunized gld and lpr mice
At the termination of each experiment, 48-h DTH responses were
measured. Lymph nodes and spleens were processed for proliferation assays and for determination of cytokine production to IRBP.
In contrast to the striking inhibition of disease scores, DTH responses of gld or lpr mice immunized with either 125 or 200 ␮g
IRBP were not different from the responses of WT mice (Fig. 1B),
indicating that adequate priming had taken place. Because EAU is
driven by a cell-mediated pathology, DTH responses of the gld and
lpr mutants are an important measure of their immunocompetence
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
IRBP was isolated from bovine retinas by Con A-Sepharose affinity chromatography and fast performance liquid chromatography, as described previously (16). BSA, ␣-methyl-D-mannopyranoside (␣-MMP), Con A, pertussis toxin (PTX), CFA, and conalbumin were purchased from Sigma (St.
Louis, MO). NeutroAvidin (HRP conjugated) was purchased from Pierce
(Rockford, IL). Mycobacterium tuberculosis strain H37RA was purchased
from Difco (Detroit, MI). ELISA kits and minikits for cytokine measurement were purchased from Endogen (Woburn, MA). All Abs for flow
cytometry were purchased from Becton Dickinson-PharMingen (La
Jolla, CA).
5481
5482
Fas AND FasL CONTROL OF EAU
FIGURE 2. IRBP-specific cytokine production by splenocytes of gld,
lpr, and WT mice. Spleens harvested 21 days after immunization were
pooled within groups, and cultures of 5 ⫻ 106 cells/ml were stimulated
with IRBP. Shown is cytokine content as assayed by ELISA in supernatants collected after 48 h. Cytokine production by IRBP-stimulated cells
from naive WT, lpr, and gld mice was uniformly at or below the level of
detection, which was 0.137, 0.111, 0.008, and 0.008 ng/ml for IFN-␥,
IL-10, IL-4, and IL-5, respectively.
to mount a cell-mediated in vivo response. Proliferative responses
in culture to IRBP in lpr and gld mice were detectably lower than
in B6 WT, with lpr appearing to be more affected than gld (Fig.
1C). In three repeat experiments, the response of gld mice was on
average 73% of WT, and of lpr mice 42% of WT, when immunized with an equivalent amount of IRBP. Furthermore, both gld
and lpr showed markedly decreased production of IFN-␥ (Fig. 2).
IL-10 and IL-5 were also affected, although to a lesser degree, and
IL-4 production was diminished only in the lpr. Thus, across the
board, responses of lpr mice were affected more than those of gld
mice. In addition, the Th1 response, as represented by Ag-specific
IFN-␥ production, appeared to be compromised to a greater degree
than the Th2 response, as represented by Ag-specific IL-4, IL-5,
and IL-10. Thus, the gld and lpr mutants appeared to be developing a Th1-low cellular response to IRBP.
Whether the altered cytokine profile indicates an altered interaction with APC in these mice, or another type of relative immune
deficit, is unclear. It is well known that gld and lpr mice with time
accumulate nonfunctional double-negative lymphocytes that are
not responsive to Ag. Although most mice used in this study were
under 3 mo of age, at the finite cell numbers of cells present in the
culture dish such double-negative cells could dilute the Ag-reactive cells, explaining at least in part the reduced immunological
responses in vitro. More important, however, the ability of both lpr
and gld mice to develop good DTH responses after active immunization with IRBP indicates that at the level of the organism they
were able to prime and recruit adequate numbers of effector cells.
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
FIGURE 1. Disease and immunological responses of gld, lpr, and WT mice immunized with IRBP 21 days after immunization with the indicated dose
of IRBP. Data are compiled from six experiments, four of which were done with mice 2–2.5 mo old, and two with mice 2– 6 mo old (most ⬍4 mo). A,
EAU scores by histopathology. Disease is graded on a scale of 0 – 4 by a masked observer. Each point represents one mouse (average of both eyes), and
the horizontal lines show the average score of the group. B, DTH responses in micrometers of the same mice. DTH was measured by ear swelling 48 h
after challenge and is presented as the difference between the thickness of the IRBP-injected ear and the PBS-injected ear. Each point is one mouse, with
the horizontal line showing the average of the group. The EAU scores of gld vs their WT controls, and lpr vs their WT controls are significantly different
(p ⬍ 0.05). The DTH scores do not differ. Naive mice uniformly had an EAU score of 0. Average DTH to IRBP in naive mice was 1.2, 0.3, and 1.3 ␮m
for WT, gld, and lpr (n ⫽ 13, 6, and 6), respectively. C, Proliferation of draining lymph node cells to IRBP (30 ␮g/ml). Shown is the average difference
in cpm between IRBP-stimulated and unstimulated lymph node cells ⫾ SD of triplicate cultures (representative experiment of three). Background counts
in unstimulated control cultures ranged between 500 and 3000 cpm for the different groups. Counts in IRBP-stimulated lymph node cell cultures from naive
WT, lpr, and gld mice were the same as counts in unstimulated cultures from the same mice and well within the background range (1600 –1800 cpm).
The Journal of Immunology
5483
Ocular histopathology of normal and uveitic gld and lpr mice
Because Fas and FasL are normally expressed in retinal tissues, it
was important to examine whether the lpr and gld mutations result
in an alteration of the normal retinal architecture, which could
affect disease development. Representative histopathologic sections of retina from normal and diseased gld, lpr, and WT mice are
shown in Fig. 3. The histopathology images shown correspond to
disease scores of 0, 0.5, and 2. Importantly, no changes in ocular
architecture or nonspecific accumulations of lymphocytes were observed in the retinas of unimmunized gld or lpr mice. EAU histology in gld or lpr mice resembled typical changes seen in WT
mice at the equivalent disease grade, with a combination of cellular
infiltrate and typical retinal folding and/or destruction of the photoreceptor cell layer. It should be kept in mind that EAU scores of
2 for gld and lpr mice are not representative of the average, and are
shown only for illustrative purposes.
Normal expression of Fas and FasL on cells of the immune
system is required for full induction of EAU
To elucidate whether the diminished induction of EAU in gld or
lpr mice results from a defect at the level of the tissue or the
immune system, we initially performed adoptive transfers of
primed T cells that had been Ag stimulated in culture, from WT
into gld or lpr mice, and vice versa. Due to the limited number of
mutant mice available, and because the most disease-permissive
situation is transfer into B6, the additional controls of homologous
gld3gld and lpr3lpr transfers was omitted. The results of these
adoptive transfer experiments were reminiscent of the results after
active immunization, i.e., gld and lpr mice developed markedly
less disease than the WT (Fig. 4). Interestingly, gld recipients of
WT cells had reduced EAU scores, despite having DTH responses
equivalent to WT. lpr recipients of WT cells did not appear to
develop either EAU or DTH responses. Transfer of mutant cells
into either WT or the reciprocal mutant recipients induced diminished DTH responses and diminished EAU scores.
Because EAU expression is heavily dependent on recruited nonspecific inflammatory leukocytes, such adoptively transferred
EAU is caused by a mixed population of effectors. The Ag-specific
T cells come from the donor, and the nonspecific recruited leukocytes come from the host. The data with respect to the role of Fas
and FasL on immunocytes vs tissue are therefore difficult to interpret. To create a situation in which both the Ag-specific and the
recruited cells come from the donor, we produced lethally irradiated BM chimeras, as described in Materials and Methods, in
which WT, gld, or lpr mice served as either hosts or donors. WT,
gld, and lpr hosts receiving WT lymphocytes all developed EAU
with an average grade and range of scores that were not significantly different from one another (Fig. 5A). In contrast, WT hosts
receiving gld or lpr lymphocytes did not develop significant EAU.
Interestingly, although WT as well as lpr recipients of gld BM did
develop appreciable DTH, there was no EAU whatsoever in these
recipients, suggesting that FasL on cells of the immune system was
needed for effecting the tissue damage typical of EAU, but not for
effecting DTH. Gld recipients of lpr lymphocytes exhibited progressive morbidity after immunization for EAU induction, and had
to be sacrificed on day 15 rather than day 21, which made interpretation of these data difficult. Nevertheless, since EAU onset in
B6 mice is between days 12 and 14 after immunization, they had
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
FIGURE 3. Ocular histology of normal and uveitic mutant and WT mice. Eyes harvested 21 days after immunization were stained with hematoxylineosin. Note that normal or diseased histology does not differ among genotypes. Shown are sections of eyes with disease scores of 0, 0.5, or 2 for all
genotypes. Scores of 2 for lpr and gld are not typical for those genotypes and are shown only for comparison. Original magnification, ⫻200.
5484
at least in theory enough time to develop EAU, had they been able
to do so. In the aggregate, these data support the hypothesis that
normal expression of Fas and of FasL on cells of the immune
system is required for full induction of EAU, but their expression
at the level of the tissue is not required for EAU pathogenesis.
Cellular responses in BM chimeras immunized for EAU
induction
Cellular responses to IRBP were measured in the various BM chimera combinations 21 days after immunization. As shown in Fig.
5B, 48-h DTH responses in WT, gld, or lpr mice receiving WT
lymphocytes were not significantly different, corresponding to the
disease scores shown in Fig. 5A. Fig. 5C shows a representative
proliferation experiment comparing IRBP-specific splenocyte proliferation of the different BM chimera groups. Interestingly, proliferative responses of splenocytes from recipients of WT lymphocytes (Fig. 5C) did not correspond to EAU disease scores (Fig.
5A), with splenocyte proliferation of gld or lpr recipients of WT
lymphocytes considerably less than WT recipients of WT lymphocytes, although their EAU scores were the same. This suggests that
in vitro proliferative responses do not necessarily correspond to
pathogenicity. Although neither WT nor lpr recipients of gld lymphocytes developed EAU (Fig. 5A), these mice had measurable
FIGURE 5. Disease and immunological responses of radiation BM chimeras of gld, lpr, and WT mice immunized with IRBP. Gld, lpr, and WT
mice serve as host or donor, as indicated. All mice were entered into the
experiment at 2–2.5 mo of age. Mice were immunized with 125 ␮g of
IRBP. Eyes and tissues were collected 21 days after immunization, as
described in the legend to Fig. 1. A, EAU scores; B, 48-h DTH responses.
There is no statistically significant difference between the three groups who
received B6 BM either in EAU or in DTH. DTH of gld BM recipients
differs from B6 and gld recipients of B6 BM recipients, but not from lpr
recipients of B6 BM or from each other. C, IRBP-specific spleen cell
proliferation as average cpm of triplicate cultures after background subtraction ⫾ SD (representative experiment of two). Background counts were
between 600 and 2700 cpm, depending on the group. Because of the limited number of mutant mice available, and because the most disease-permissive situation is transfer into B6, the additional control of homologous
gld3gld and lpr3lpr transfers was omitted. †, Dead.
DTH responses (Fig. 5B) and splenocyte proliferation (Fig. 5C).
Recipients of lpr BM did not develop either EAU or immunological responses (responses were measured only in wild type; proliferation and DTH of gld recipients, which experienced morbidity
and had to be sacrificed early, were not measured). Control BM
chimeras of lpr donor cells in lpr recipients did not develop morbidity. Thus, lpr-derived BM appeared to be unable to reconstitute
either WT or gld recipients, and therefore the results from this
donor-recipient combination must be interpreted with caution.
Discussion
In the present study, we have shown that mice homozygous for the
gld or lpr defect on the C57BL/6 background had a reduced susceptibility to induction of EAU by immunization. They also had a
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
FIGURE 4. EAU scores (A) and DTH scores (B) in adoptive transfer
recipients of primed T cells. Recipients were injected i.p. with 40 ⫻ 106
lymphoid cells obtained from IRBP-primed donors and cultured for 3 days
with IRBP. Recipients were challenged for DTH after 8 days; responses
were read, and eyes were harvested 10 days after adoptive transfer. Shown
are EAU scores by histopathology on a scale of 0 – 4, and DTH measurements as Ag-specific ear swelling in micrometers. Mice were 2–5 mo of
age. EAU scores of gld and lpr recipients of B6 cells differ significantly
from those of B6 recipients. DTH scores of lpr recipients, but not gld
recipients, are statistically different from B6 recipients. (Statistics for the
other combinations were not done due to the small size of the groups.)
Fas AND FasL CONTROL OF EAU
The Journal of Immunology
In light of the possibility that Fas and FasL on the tissue may not
be involved in pathogenesis of EAU, the question that arises is:
why would expression of these molecules be needed on the effector
cells to induce disease? The process of apoptosis is an active one,
and leukocytes signaled through Fas and FasL activate a variety of
genes. It is conceivable that some of these genes might be involved
in the effector function of these cells. Recent reports describe the
chemoattractant ability of FasL for polymorphonuclear neutrophils
(26, 27) and the T cell costimulatory capacity of Fas (28 –30).
Furthermore, engaging Fas with an anti-Fas Ab has been shown to
induce IL-8 secretion, which also is chemotactic for neutrophils
(31). Although neutrophils are not the predominant infiltrating
population in the eye, they appear to have a role in the photoreceptor cell damage that is typical of EAU (32, 33). However, it
should be kept in mind that the studies demonstrating the T cell
costimulatory activity of Fas all used anti-Fas Abs, which can elicit
different effects than engagement of Fas by its natural ligand (34).
Up-regulated levels of FasL on lpr lymphocytes might also affect
the interaction of T cells from these mice with Fas-expressing
APC, resulting in altered or diminished priming.
In conclusion, the data presented in this work are compatible
with the interpretation that in the uveitis model in mice, normal
expression of the Fas and FasL molecules is required on cells of
the immune system to effect the pathology typical of EAU. In
contrast, the ability to express Fas and FasL on the target tissue
does not seem to affect disease induction.
Acknowledgments
We thank Dr. Tom Ferguson of Washington University for his generous
gift of gld and lpr breeder mice on a C57BL/6 background whose progeny
was used in the initial experiments. We thank Phyllis Silver for her help in
performing some of the experiments in this study.
References
1. Sanui, H., T. M. Redmond, S. Kotake, B. Wiggert, L. H. Hu, H. Margalit,
J. A. Berzofsky, G. J. Chader, and I. Gery. 1989. Identification of an immunodominant and highly immunopathogenic determinant in the retinal interphotoreceptor retinoid-binding protein (IRBP). J. Exp. Med. 169:1947.
2. Caspi, R. R., F. G. Roberge, C. G. McAllister, M. el-Saied, T. Kuwabara, I. Gery,
E. Hanna, and R. B. Nussenblatt. 1986. T cell lines mediating experimental autoimmune uveoretinitis (EAU) in the rat. J. Immunol. 136:928.
3. Rizzo, L. V., P. Silver, B. Wiggert, F. Hakim, R. T. Gazzinelli, C. C. Chan, and
R. R. Caspi. 1996. Establishment and characterization of a murine CD4⫹ T cell
line and clone that induce experimental autoimmune uveoretinitis in B10.A mice.
J. Immunol. 156:1654.
4. Gery, I., M. Mochizuki, and R. B. Nussenblatt. 1986. Retinal specific antigens
and immunopathogenic processes they provoke. Prog. Retinal Res. 5:75.
5. Nagata, S., and P. Golstein. 1995. The Fas death factor. Science 267:1449.
6. Krammer, P. H. 1999. CD95(APO-1/Fas)-mediated apoptosis: live and let die.
Adv. Immunol. 71:163.
7. Griffith, T. S., T. Brunner, S. M. Fletcher, D. R. Green, and T. A. Ferguson. 1995.
Fas ligand-induced apoptosis as a mechanism of immune privilege. Science 270:
1189.
8. Griffith, T. S., X. Yu, J. M. Herndon, D. R. Green, and T. A. Ferguson. 1996.
CD95-induced apoptosis of lymphocytes in an immune privileged site induces
immunological tolerance. Immunity 5:7.
9. Chan, C. C., D. M. Matteson, Q. Li, S. M. Whitcup, and R. B. Nussenblatt. 1997.
Apoptosis in patients with posterior uveitis. Arch. Ophthalmol. 115:1559.
10. Takahashi, T., M. Tanaka, C. I. Brannan, N. A. Jenkins, N. G. Copeland, T. Suda,
and S. Nagata. 1994. Generalized lymphoproliferative disease in mice, caused by
a point mutation in the Fas ligand. Cell 76:969.
11. Watanabe-Fukunaga, R., C. I. Brannan, N. G. Copeland, N. A. Jenkins, and
S. Nagata. 1992. Lymphoproliferation disorder in mice explained by defects in
Fas antigen that mediates apoptosis. Nature 356:314.
12. Cohen, P. L., and R. A. Eisenberg. 1991. Lpr and gld: single gene models of
systemic autoimmunity and lymphoproliferative disease. Annu. Rev. Immunol.
9:243.
13. Sabelko, K. A., K. A. Kelly, M. H. Nahm, A. H. Cross, and J. H. Russell. 1997.
Fas and Fas ligand enhance the pathogenesis of experimental allergic encephalomyelitis, but are not essential for immune privilege in the central nervous system. J. Immunol. 159:3096.
14. Waldner, H., R. A. Sobel, E. Howard, and V. K. Kuchroo. 1997. Fas- and FasLdeficient mice are resistant to induction of autoimmune encephalomyelitis. J. Immunol. 159:3100.
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
reduced capacity to develop disease in response to adoptive transfer of primed WT lymph node cells. However, radiation chimeras
transplanted with WT BM developed normal disease scores following immunization. Conversely, lpr and gld lymphoid cells invariably were unable to support EAU induction in WT hosts, and
in some combinations were unable to elicit DTH, irrespective of
whether they were transferred as Ag-primed cells, or as a reconstituting BM inoculum.
The combination of donor-host relationships used in this study
is complex. In the unmanipulated mouse, the target tissue as well
as the entire immune system have the same genetic makeup. In the
adoptive transfer recipients, the Ag-specific T cells come from the
donor, but the target tissue as well as the recruited nonspecific
leukocytes come from the host. In the BM chimera, the target
tissue comes from the host, and the entire immune system comes
from the donor. Some chimeras, particularly those that received lpr
donor cells, showed signs of a graft-vs-host-like wasting syndrome
that has been described (19, 20), and have been attributed at least
in part to constitutive up-regulation of FasL on lpr donor T cells
(21, 22). Although WT recipients of lpr donor cells appeared to
show some weakness, most survived until termination of the experiment 21 days after immunization. The wasting syndrome was
more pronounced in gld recipients of lpr donor cells, and as a
result these mice were euthanized 15 days after immunization.
Data from these adoptive transfers should therefore be interpreted
with caution. Despite the difficulty in interpreting the data from
some of the combinations, the result that all the BM chimeras
receiving WT BM, and only they, developed full-blown EAU of
essentially equivalent intensity leads to several conclusions: 1) to
effectively induce EAU, cells of the immune system must have
normal expression of Fas and FasL; 2) expression of Fas and FasL
matters not only on the Ag-specific T cells, but also on the recruited nonspecific host leukocytes; 3) the ocular cells do not need
to express Fas for tissue damage to occur; and 4) lack of FasL
expression in the eye does not result under these conditions in
exacerbated expression of disease.
In view of the published literature, these results were unexpected. Constitutive expression of FasL on ocular tissue is considered part of ocular immune privilege and an important protective mechanism against inflammatory responses in the eye by
signaling for death of invading Fas-positive inflammatory cells (7,
8). Signaling for cell death of Fas-expressing target tissues by
FasL-expressing activated T cells, or even neighboring target tissue cells, has been proposed as a common pathogenic mechanism
for tissue destruction in organ-specific autoimmune diseases (23,
24). In line with these paradigms, Sabelko-Downes et al. (15),
working in the EAE model, reported that FasL expression on donor
effector cells and Fas expression on recipient target tissue are required for clinical development of disease. Applied to uveitis,
these paradigms lead to the predictions that retinal cells that cannot
deliver the death signal to effector T cells (gld) should be more
susceptible to tissue damage, that retinal cells that cannot be given
the death signal (lpr) should exhibit less pathology, and finally,
that effector cells that cannot be signaled to die (lpr) should cause
more severe disease. Unexpectedly, although FasL as well as Fas
are constitutively expressed on murine and human ocular tissue,
and are up-regulated during ocular inflammation (C.-C. Chan, unpublished observations; Refs. 7, 9), the present data point to the
conclusion that neither lack of Fas nor lack of FasL on ocular
tissue alters expression of disease. Nevertheless, our results do not
exclude the possibility that apoptosis by mechanisms other than
through Fas/FasL interaction, such as the recently described proapoptotic effects of aqueous humor on inflammatory cell types
(25), may play a role in EAU pathology in this system.
5485
5486
25. D’Orazio, T. J., B. M. DeMarco, E. S. Mayhew, and J. Y. Niederkorn. 1999.
Effect of aqueous humor on apoptosis of inflammatory cell types. Invest. Ophthalmol. Visual Sci. 40:1418.
26. Chen, J. J., Y. Sun, and G. J. Nabel. 1998. Regulation of the proinflammatory
effects of Fas ligand (CD95L). Science 282:1714.
27. Seino, K., K. Iwabuchi, N. Kayagaki, R. Miyata, I. Nagaoka, A. Matsuzawa,
K. Fukao, H. Yagita, and K. Okumura. 1998. Chemotactic activity of soluble Fas
ligand against phagocytes. J. Immunol. 161:4484.
28. Alderson, M. R., R. J. Armitage, E. Maraskovsky, T. W. Tough, E. Roux,
K. Schooley, F. Ramsdell, and D. H. Lynch. 1993. Fas transduces activation
signals in normal human T lymphocytes. J. Exp. Med. 178:2231.
29. Alderson, M. R., T. W. Tough, S. Braddy, T. Davis-Smith, E. Roux, K. Schooley,
R. E. Miller, and D. H. Lynch. 1994. Regulation of apoptosis and T cell activation
by Fas-specific mAb. Int. Immunol. 6:1799.
30. Biancone, L., A. D. Martino, V. Orlandi, P. G. Conaldi, A. Toniolo, and
G. Camussi. 1997. Development of inflammatory angiogenesis by local stimulation of Fas in vivo. J. Exp. Med. 186:147.
31. Sekine, C., H. Yagita, T. Kobata, T. Hasunuma, K. Nishioka, and K. Okumura.
1996. Fas-mediated stimulation induces IL-8 secretion by rheumatoid arthritis
synoviocytes independently of CPP32-mediated apoptosis. Biochem. Biophys.
Res. Commun. 228:14.
32. Gritz, D. C., C. Montes, L. R. Atalla, G. S. Wu, A. Sevanian, and N. A. Rao.
1991. Histochemical localization of superoxide production in experimental autoimmune uveitis. Curr. Eye Res. 10:927.
33. Goto, H., N. Yamakawa, M. Hasemi, G. Matsuura, and M. Usui. 1994. Superoxide generated by polymorphonuclear leukocytes and retinal lipid peroxidation
in uveoretinitis. Nippon Ganka Gakkai Zasshi 98:1019.
34. Thilenius, A. R., K. Braun, and J. H. Russell. 1997. Agonist antibody and Fas
ligand mediate different sensitivity to death in the signaling pathways of Fas and
cytoplasmic mutants. Eur. J. Immunol. 27:1108.
Downloaded from http://www.jimmunol.org/ by guest on June 18, 2017
15. Sabelko-Downes, K. A., A. H. Cross, and J. H. Russell. 1999. Dual role for Fas
ligand in the initiation of and recovery from experimental allergic encephalomyelitis. J. Exp. Med. 189:1195.
16. Pepperberg, D. R., T. L. Okajima, B. Wiggert, H. Ripps, R. K. Crouch, and
G. J. Chader. 1993. Interphotoreceptor retinoid-binding protein (IRBP): molecular biology and physiological role in the visual cycle of rhodopsin. Mol. Neurobiol. 7:61.
17. Chan, C. C., R. R. Caspi, M. Ni, W. C. Leake, B. Wiggert, G. J. Chader, and
R. B. Nussenblatt. 1990. Pathology of experimental autoimmune uveoretinitis in
mice. J. Autoimmun. 3:247.
18. Snedecor, G. W., and W. G. Cochran. 1967. Statistical Methods, 6th Ed. Iowa
State University Press, Ames, p. 246.
19. Perkins, D. L., J. Michaelson, R. M. Glaser, and A. Marshak-Rothstein. 1987.
Selective elimination of non-lpr lymphoid cells in mice undergoing lpr-mediated
graft-vs-host disease. J. Immunol. 139:1406.
20. Theofilopoulos, A. N., R. S. Balderas, Y. Gozes, M. T. Aguado, L. M. Hang,
P. R. Morrow, and F. J. Dixon. 1985. Association of lpr gene with graft-vs.-host
disease-like syndrome. J. Exp. Med. 162:1.
21. Chu, J. L., P. Ramos, A. Rosendorff, J. Nikolic-Zugic, E. Lacy, A. Matsuzawa,
and K. B. Elkon. 1995. Massive up-regulation of the Fas ligand in lpr and gld
mice: implications for Fas regulation and the graft-versus-host disease-like wasting syndrome. J. Exp. Med. 181:393.
22. Watanabe, D., T. Suda, H. Hashimoto, and S. Nagata. 1995. Constitutive activation of the Fas ligand gene in mouse lymphoproliferative disorders. EMBO J.
14:12.
23. De Maria, R., and R. Testi. 1998. Fas-FasL interactions: a common pathogenetic
mechanism in organ-specific autoimmunity. Immunol. Today 19:121.
24. Sakata, K., A. Sakata, L. Kong, H. Dang, and N. Talal. 1998. Role of Fas/FasL
interaction in physiology and pathology: the good and the bad. Clin. Immunol.
Immunopathol. 87:1.
Fas AND FasL CONTROL OF EAU